FR2771415A1 - Coloured powders useful as pigments - Google Patents

Abstract

Coloured powders useful as pigments are selected from 91 irradiated mineral powders listed within a table of 1667 entries indicating the nature of the mineral and the irradiation conditions, the powders being irradiated before or after application to a material to be coloured. Also claimed is a method for modifying the colour of an irradiatable material, comprising applying a mineral powder onto or into the material and irradiating the material and powder. Also claimed is a process for preparing a coloured powder for use as a pigment, comprising irradiating a mineral powder as indicated in the table for the above 91 powders.

Description

COLORED POWDER OBTAINED BY PHYSICAL TREATMENT
This application is a division of application no. 9612163
deposited on 2 October 1 996
Technical field of the invention
The present invention relates to new colored powders forming a "system" of natural colors covering the entire visible spectrum and offering an enormous variety of hues, tones and reflections from white to black through all colors of the rainbow.

 The invention also relates to the preparation of these new powders.

 The invention finally relates to the use of these new powders as pigments for coloring materials, especially those used for a decorative or ornamental purpose, and more specifically those used in the fields of construction and architecture.

 In the description and in the claims that follow, "color system" is understood to mean a set of natural colors organized logically according to the natural order of the colors of the rainbow, starting with white and ending with black. This system includes so-called "flat" colors, namely which, in pure form, are without hue and without reflection, and colors which, in the pure state, can have tones, hues and / or reflections . This system also includes mixtures of two or more of these colors. From a practical point of view, the colors in question are in the form of powders directly usable as pigments, or in the form of materials in or on which powders have been applied and subsequently subjected to one or more heat treatments and / or or one or more irradiations.

History of the invention
There are many natural minerals or industrial pigments available in nature or on the market. However, experience shows that the range of colors they provide does not cover, by far, the entire visible spectrum. For example, there are practically no blue or green minerals or pigments.

 By carrying out systematic tests of chemical treatment more or less prolonged with acids or other reagents and / or by subjecting certain minerals heat treatments or irradiations more or less prolonged to X-rays or gamma before or after incorporation of these From the minerals to the materials to be colored, it has been discovered that it is possible to obtain powders or colored materials of practically all the hues, all the tones and all the textures, which together constitute an almost infinite range of natural colors.

 A detailed list of all the transformed powders and all the colored materials which could thus be prepared is given in the annexed Table. In this Table, the transformed powders and the colored materials are numbered 1 to 1 667 and are classified according to their colors and their tones, in the following order: white (including white, ivory and cream), lilac, violet, blue, green, yellow, orange, pink, red, beige, brown, gray and black.

 For each powder or material thus listed, the color, tone or hue obtained are indicated; the identification number assigned to that powder or material; the number, process of a "sharp" mineral used as a starting material (see paragraph below); the name of the other metal (s), minerals or compounds, if any, the name and composition of the material on or in which the powder (s) has been applied and the process used to obtain the given color.

 It should be mentioned that the attached Table also contains, in its preamble, a list of natural minerals used as starting materials for the preparation of the powders or materials according to the invention. These natural minerals are numbered # 1 to # 1 1 3 (the "sharp" is used to distinguish them from others). For each of these minerals, its denomination, place of origin and colors in stone and powder are also indicated before it has undergone any treatment.

Obiet and summary of the invention
The main subject of the present invention is therefore new colored powders that can be used as pigments, which powders are obtained by chemical, thermal and / or physical treatment (irradiation) carried out before or after application. The powders thus forming the subject of the invention are numbered 1 to 1 669 in the attached Table.

 The subject of the invention is also the color system consisting of all the colored powders that can be used as pigments and materials in or on which colored powders have been applied and subsequently subjected to one or more heat treatments and / or one or more radiation. More specifically, it has a second object a color system consisting of powders used as pigments and pigmented materials and heat treated and / or irradiation, whose colors extend over almost the entire visible spectrum. This system is characterized in that it consists of all the powders and materials of different colors listed in the Table.

 The invention further relates to the use as a pigment of each of the colored powders of the color system mentioned above.

Detailed description of the invention
As previously indicated, the subject of the invention is a color system consisting of a set composed of colored powders of mineral origin obtained by mechanical, thermal, chemical and / or physical processes and materials in or on which mineral powders. have been applied and subsequently subjected to one or more heat treatments and / or one or more irradiations. This system is particularly original in the. as the colors of the powders and materials that constitute it extend over almost the entire visible spectrum and cover an almost infinite number of hues, tones and reflections.

 The nature of each of the powders of the system according to the invention and the way in which this powder can be prepared are fully defined in the Table, as already explained above.

 The powders of the color system according to the invention can be used as pigments in a very large number of fields. Among these possible uses, the coloring of modern architectural materials is certainly the most interesting because of the mineral nature of the powders in question.

"Modern architectural materials" means the various materials used in the three main areas of development, namely:
1) the architecture itself, that is to say the structural elements of a building or its complementary, as for example, the windows;
2) interior design, that is to say the coating of the internal walls of a building, its furniture, wallpaper, draperies, etc .; and
3) exterior landscaping, such as the exterior cladding of a building.

 Amongst the materials thus colorable and used on a large scale for the manufacture of structural elements of buildings, mention may first of all be made of concrete, resins, polymers and other plastics.

 Among the amenable materials related to interior or exterior arrangements, mention may be made of arborite, ink, paper pulp, glass, ceramics, fabrics or metal coatings, in particular based on aluminum, stainless steel, black or galvanized sheet, copper, brass, etc ...

 While the use of the powders according to the invention as pigments for coloring modern architectural materials is very interesting and promising, it should be mentioned that the invention is not restricted solely to this use. Thus, the powders according to the invention can also be used as pigments in a very large number of other fields which do not really affect the sector of the construction of buildings. For example, the coloring of paints used to paint the lines on highways, where the use of the powders according to the invention as pigments could not only serve to obtain the desired coloration but also to obtain interesting mechanical characteristics, such as for example, better friction resistance of car tires and thus less wear on the lines, reducing their need for frequent replacement. It is also possible to envisage the use of the powders obtained according to the invention as pigments in rubber, linoleum, lard, make-up, mosaics for floors, artistic paints, etc.

Preparation of colored powders according to the invention
As is clear from the attached Table, the colored powders according to the invention are obtained by methods known per se, which are used either alone or in combination.

These methods can be;
- purely mechanical (grinding, mixing, ...);
- purely thermal (heating or calcination);
- purely chemical (reaction with acids, ammonia or other reagents);
- purely physical (irradiation with UV, IR, rays, ...); or
a combination of one or more of the above methods, in any order.

Mechanical process
By "mechanical process" is meant grinding, sieving and any mixing of one or more powders.

 The powders obtained by a purely mechanical process (simple grinding and optional mixing with one or more other powders) are, from a practical point of view, excluded from the appended claims.

Thermal process
The heat treatment process used for the synthesis of several of the powders according to the invention consists essentially of heating or calcining a mineral or a mixture of preselected minerals at a temperature up to 12600C for a period of 30 minutes to 10 hours. This process transforms the color or color quality of the treated mineral (s). The heat source may be an oven, a direct flame such as a torch, a laser beam, or any other heating means. This process is carried out in ambient air or in a controlled atmosphere.

 From a practical point of view the mineral used may be in the form of powder or stone. It can also be in the pure state or in the form of a mixture with one or more other minerals or metals. This mineral can be moistened and / or stirred before, during or after the treatment, in order to invigorate the color and sometimes even modify it. Cooling can be fast or slow. The method may also include alternating periods of heat treatment and cooling.

 It should be mentioned that the variation of the heat treatment modalities causes variations in color or color quality. In fact, the number of these variations is infinite.

 As non-limiting examples of implementation of this thermal process, reference may be made to the description given in the Table of powders numbered 753 (conventional heat treatment), 994-5 (heat treatment controlled over time) or 1 635-6 (heat treatment under inert atmosphere).

 In the foregoing description, reference has been made exclusively to direct processing of pre-selected minerals. This same process can, however, be used successfully after application of said minerals in or on a material to be colored. Once this application is complete, we obtain a given color or color quality. After heat treatment of said material, another color or color quality is obtained. There is therefore transformation of the powder in the material with, as a result, a simultaneous transformation of colors.

 This is interesting in that the color obtained after the heat treatment often differs from that obtained when the same mineral is heat-treated under the same conditions, but independently of the material. This process multiplies the colors that can be obtained with the same mineral.

 The materials in question here are numerous. They include polyester resin, cement, metal, porcelain, glass, and stone.

 As non-limiting examples of implementation of this thermal process after application on or in a material, reference may be made to the description given in Table of powders Nos. 1 to 20 (after application to the stone ); 1,392 (after acid treatment and application in polyester resin); 455 (after acid treatment, heat treatment, ammonia treatment and application in polyester resin); 461 to 464 (application on metal); 810 (application on glass); etc ...

Chemical process
By chemical process is meant the treatment of a mineral and / or several minerals mixed with other additives, with a reagent, such as a strong acid, ammonia, cyanide, ether, etc. ...

 The treatment with the acids can be carried out in an acid bath with a single acid or a combination of acids selected from hydrochloric acid, nitric acid, sulfuric acid, phosphoric acid, tartaric acid, acetic acid and hydrofluoric acid. The colors or color qualities of the same mineral vary from one acid to another or from one combination of acids to another. The treatment can be performed in ambient air and is of a duration ranging between an immediate withdrawal and several years. The duration of the soaking also determines the color or the color quality. The distribution of the mass of the mineral, either horizontally or vertically (in column form) in the acid bath, influences the colors obtained with certain minerals.

 Drying can vary and can determine the color. This drying may be natural or may be carried out on a hot plate, in an oven, in an oven or on a sand bath. During the drying step, the temperature can be varied to dry the solution or bring it to a boiling point and then remove or maintain it. Too much heat can burn or brown some minerals. For other minerals, the color intensifies when the heat is very high.

 Acid treatment therefore transforms the color or color quality of the minerals deeply and sustainably. This treatment makes it possible to obtain colors that are not found in natural minerals. It allows in particular to obtain diversified colors, unusual and in the pure state, that is to say without mixing with other minerals or chemical or metallic compounds. In this regard, it should be noted that the treatment with phosphoric acid has made all the treated minerals fluorescent.

 From a practical point of view, the mineral preferably, but not necessarily reduced to the state of powder or stone, can be treated in ambient air or in a controlled atmosphere. The amount of mineral can be chosen just like that of the acid, making sure however that the mineral is completely covered. Variations in the proportions of the mineral and the acid will bring variations in the color and the quality of the color. Similarly, variations in the methodology followed (soaking and / or drying time, nature of the acid bath (s) used, new or used, degree of dilution of this bath, use of a single acid or a mixture of acids, treatment (s) single or successive with the same acid, several different acids or even other reagents, such as ammonia, etc ...) will bring variations in the color or color quality.

 As previously indicated, the powders obtained with the combination of a mineral, previously heated or not, and an acid or a combination of acids may be taken up and treated with another reagent, such as ammonia, according to the various modalities presented above.

These powders can also be calcined at various temperatures in the open air or in a controlled atmosphere.

 As non-limiting examples of implementation of this acid chemical treatment method, reference may be made to the description given in the Table of powders numbered 280, 286 (acid treatment only), 267 or 367 (acid treatment with heat treatment) or 255 and 273-275 (acid treatment, with heat treatments and ammonia).

In place of one or more acids, other reagents can be used, for example:
- the ether in which the mineral can be soaked for a
given duration, the drying then taking place
natural - see, as non-limiting examples, the
description given in the Table of powders
numbered 492 (ether treatment alone), (treatment
thermal and then with ether) or 209 (treatment with acid then
with ether) -;
- ammonia, where, as with acids, the same
variations in the treatment conditions give
different colors or qualities of color - see, as
non-limiting examples, the description given in the
Table of powders numbered 1 88, 293 to 298
(treatment with ammonia alone); 369, 390 (treatment
thermal and ammonia), ...;
- cyanide - see, as examples, the description given
in the Table of powders numbered 868 or 1,246.

Physical process (irradiation)
The irradiation treatment method is applicable to all minerals, whether in the single state or in the form of a mixture.

 This radiation treatment method, which is also applicable in materials including minerals, transforms the color or color quality of said minerals. For some minerals, changes in texture, structure (crystallization) or transparency sometimes accompany the change in color or color quality.

 Several types of irradiation can be used, including X, gamma, electron, neutron or laser radiation. It is also possible to radiate successively the same mineral with a first type of radiation and then with a second type of radiation. By way of nonlimiting examples of such a combination of irradiation, reference may be made to the description given in the Table of powders numbered 82 (electron and gamma radiation), 239 (electron and neutron radiation), 1660 (radiation neutron and gamma) and 1174 (electron and X radiation).

In general, the irradiation can be carried out continuously or discontinuously in ambient air or in a controlled atmosphere. Minerals can be irradiated either at normal temperature, or warm or cooled after heat treatment. The same mineral irradiated at various doses makes it possible to obtain a range of colors or color qualities. The reaction of the mineral to irradiation varies from one type of mineral to another. The color of some changes or increases slightly with each increase in the applied dose. This process is sometimes accompanied by significant modification thresholds. Some minerals, initially colorless, are colored by irradiation.
a) Gamma radiation
Conclusive tests were performed at doses ranging from 0.01 to 600 Mrad.

 Specifically, tests were performed in a UC-1 5 calibrator at the Canadian Irradiation Center (Institut Armand Frappier) at variable doses up to 600 Mrad.

Other tests were conducted in a Gammacells 220, manufactured by Atomic Energy of Canada Limited, with a source of 6360 cobalt-60 Curies. The measurement certificate for this device indicated
5.01 x 10 + 2.1% rad per hour.
b) Neutron refoundation
Here again, conclusive tests were carried out in a slow thermal neutron flux, for about 5 hours in the reactor of
12 2
McMaster University in Hamilton, Ontario, 10 neutrons / cm / sec.

Other tests were carried out in a mixed neutron and gamma ray flux in the nuclear reactor of the Institute of Energetic Engineering at Ecole Polytechnique in Montreal. Samples of
12 minerals were deposited in the 10 neutron / cm / sec reactor for varying periods of time to form a range of colors or color qualities. A radiation of 1,667 rad per second was emitted.
c) Electronic radiation
Successful trials were conducted in the radiology departments of the Montreal General Hospital and Notre Dame Hospital in Montreal, on minerals that were either in the form of powders inserted in gelatin capsules, or stone condition.

 The stones or capsules were placed a short distance from the collimator of a Clinace 18 device producing electrons at 18 and 20 MeV.

The total doses applied were of the order of 50 000 to 1 70 000 rad (at an application level of 5 to 500 Mp (monitor unit) per minute.
d) Refund X
Conclusive tests were carried out at the Department of Chemistry's X-ray diffraction laboratory at the University of Montreal.

The equipment used consisted of a Philips brand generator, operating a copper tube. The conditions of use were standard, ie a current of 20 mA applied for a voltage of 40 kV.

Other tests were carried out at Sainte-Justine Hospital
Montreal. Specifically, 1 39 minerals, polyester resin samples, clear and opaque white enamel paint, as well as transparent and opaque white ink samples, all pigmented with minerals, were irradiated with using a Phiiipse 250 kV therapeutic device, operating a tungsten X-ray tube, usually used for medical purposes, for 4 hours at a rate of 448 "shots" at 30-second intervals for 1/10 of second at 100 milliamps and 70 kV at a distance of 40 inches.

As non-limiting examples of implementation of this method, reference may be made to the description given in the Table of powders numbered 1174 and 1193.
e) Laser radiation
Successful tests were carried out in the laboratory of the Laser-Matière group of the INS-Energie on a Lumonics® brand Hyper EX400 excimer laser, whose amplification medium was composed of a gaseous mixture of krypton and fluorine. (KrF). This laser emits radiation
A multimode coherent UV with a wavelength of 249 nm in the form of a pulse having a duration of 30 nanoseconds and an energy of about 200 mJ. This laser was operating at a repetition rate of 20 Hz.

 From a practical point of view, the tested samples were irradiated until a change was observed or until it was damaged.

The exposure time varied from 0.5 min to 35 min; the irradiated surface was
2 0.0025 cm to 0.7 cm; laser energy from 0.160 J to 0.245 J; the flow of 2.8 W
9 2 7 2 x 10 cm at 1.0 W x 10 cm and the total energy from 2.2 J to 1300 J.

As non-limiting examples of implementation of this method, reference may be made to the description given in the Table of powders numbered 1096, 1126-7, 1545-6 and 1638.
f) Treatment nar irradiation after application
on or in a material
As in the case of the heat treatment process, the irradiation treatment can be used successfully after application of the minerals in or on a material to be colored.

 When applying a mineral on or in a material, one does not necessarily obtain an interesting result in the color (ex .: colorless, light cream, light gray or light beige). If an irradiation is then carried out, a transformation of the color or the color quality can be obtained. In most cases encountered, an irradiated mineral regardless of the material gives a color or color quality that can be radically different or similar to that obtained when the same mineral is applied in a material, and then irradiated later. In addition, the color or color quality obtained after the irradiation differs from one material to another and, moreover, from one type of radiation to another. The implementation of this process therefore makes it possible to transform the color of the minerals after their application in materials, either radically or moderately.

 The conditions for carrying out this treatment are similar to those previously described. The treated materials can also be thermally treated beforehand. Irradiation is carried out in ambient air or in a controlled atmosphere. This process is carried out at a variety of doses.

Among the sources of irradiation used are X, gamma and electronic radiation. Other sources of irradiation could also be used.

 As non-limiting examples of implementation of this method, reference may be made to the description given in the Table of powders numbered 124 (after application in PYREX @); 1,531 (after heat treatment, acid treatment and application in PYREX); 1009 (after application on cement and heat treatment); 1034 (after application in cement and heat treatment); 29 (after heat treatment, acid treatment and application in concrete polymer); 22 (after application in ink); etc ...

Application of colored powders according to the invention
As previously indicated, the powders of the color system according to the invention can be used as pigments in many fields, but more especially for the coloration of modern architectural materials. Numerous examples of colored materials according to the invention have already been mentioned (see the description above of "thermal processes" and "physical processes"). The following additional examples will illustrate, without limitation, various possible applications of the powders of the system according to the invention.

EXAMPLE 1: Application of colored powders as
pigments in plastic
Several different tests for the application of mineral pigments in transparent polyester resin have been carried out.

The procedure followed during these tests was as follows:
50 cc. of polyester resin No. 2T323 marketed by MIA
CHEMICALS were used. The chosen amount of pigments was mixed by hand with a small amount of resin and the resulting mixture was integrated with the rest of the resin. The whole thing was then stirred with a spatula and left to settle for a few minutes. The colored or tinted resin thus obtained was then transferred to another vessel and 2% by weight of polymerization catalyst was added and mixed with a spatula. After curing at 370 ° C., the resin piece obtained was demodeled, cut and polished. The color observations have been made at this stage.

 The pigments which have also been tested include, in particular, the heat-treated powder numbered 1335 in the attached Table.

 Radiation transformation tests of the colors or hues of the polyester resin parts thus prepared were also carried out. These tests carried out under the conditions given above showed that all the resin parts, whether transparent, colored or tinted, change color under the action of irradiation and that for the same pigment this color changes according to the type of irradiation used, before or after incorporation into the resin.

 This of course offers enormous possibilities of application at the decorative and / or industrial level.

EXAMPLE No. 2: Application of colored powders as
pigments in cement
Application tests of several colored powders according to the invention were carried out in Portland white cement (type 10).
ACNOR / CSA A5).

 Tests were carried out with cement mixed with a polymer composition of the type used for concretes. This composition consisted of resi numbered 152-3). It has also been noted that the addition of cement can trigger reactions. Some colors come out well in the polymer but they change in contact with the cement, which can fade or extinguish the color, giving it a milky or gray tone (see the description of the material numbered 154).

 It has further been noted that certain pigments, particularly iron oxides, are naturally drying when applied in the concrete polymer.

 Some mineral pigments therefore color the diluted cement with concrete polymer. Other pigments stain the diluted cement with concrete polymer. This depends on the nature of the pigment or the amount applied. Finally, other pigments texturize the cement diluted with concrete polymer.

 Here again, the cement may be subjected to heat treatment or irradiation as well (see description of materials numbered 147, 310 to 312, all of which have been gamma-ray treated).

EXAMPLE NO. 3: Application of a galena powder on and in
cement
Galen application tests on cement have been carried out.

 During these tests, the galena in powder form was deposited on the surface of a piece of wet or dried cement, and then subjected to a heat treatment. The fused galena formed a decorative colored glaze, the color of which varies with the chosen treatment temperature.

 As examples, reference may be made to the description given in Table of Materials numbered 427-8, 1008-9 (where radiation treatment has also been performed), 1510 and 1570-1.

EXAMPLE 4: Application of colored powders on and in
glass
a) application of a galena powder on the pane
Galena was ground to a state of fine powder. A certain quantity of this powder was deposited on a piece of glass measuring 1 "x 1" x 1/8 ", the whole was deposited in a cold furnace, the temperature rise to the desired value was progressive. cooling was carried out slowly in the oven.

The tests thus carried out have shown that the galena forms a glaze permanently adhering to the glass, and that different colors and qualities of color are obtained by varying the temperature at which the heat treatment is carried out in the same quantity. of galena applied to glass (see materials numbered 810, 1087, 1090, 1 1 75 on the
Board).

These tests have also shown that by combining galena with one or more other natural minerals (eg sulfur) or transformed, one obtains colors or qualities of different colors, to be compared with those obtained with a heat treatment of galena alone. or galena combined with a chemical (see Materials Nos. 903, 1091, 1092, 1196 on
Board).
b) application of powders in the crystal
Extremely satisfactory tests were carried out in crystal. During these tests, 1 or 2% of mineral powder was incorporated in the glass paste before blowing. The whole was mixed and melted at 13150C. The crystal thus obtained was colored or tinted, but still translucent.

As examples, reference may be made to materials numbered 266 and 565 in the Table.
c) application of powders in the white glass
Selected amounts of mineral powders were applied in 6.50 g of clear white glass powder. This glass powder was coarsely ground sintered glass, called "spruce pine batch". Since the grinding of the glass was more or less adequate, the powder used was the size of the coarse salt. After mixing, the resulting mass was deposited on a ceramic plate and the whole was heated in a Pyradias brand oven in a normal atmosphere up to 10000C. Once this temperature of 10000C was reached, the oven was turned off and the glass was left in the oven, which gradually cooled.

 This made it possible to give a color to the glass, or to give it a hue or texture.

As examples, reference may be made to materials numbered 708 or 968; 425 or 1319; 185 or 245 (very bright colors); 968 (hues); 1586 (texturization); and 872 (variegation).
d) application of powders in and on the pvrexs
Proceeding very similarly to the above, tests have been successfully carried out in Pyrex @. As examples, reference may be made to materials numbered 123, 924 and 1631.

Pyrex poucl application tests were also performed. A first test carried out with galena (see material 1173 in the Table) made it possible to obtain a matt and translucent glaze on the rounded bottom of a Pyrex test tube heated externally with the aid of an oxyacetylene torch; a second test with tellurium resulted in a milky, translucent, frost-like glaze (see material 31 in the Table); a third with molybdenum, previously heated from -180C to 7040C for 4 hours, an almost transparent glaze. Gamma irradiated, these three glazes adopting other colors or qualities of colors.
e) irradiation
As in the case of the other materials tested, the color or color quality of a glass in or on which a mineral powder according to the invention has been applied is modified by irradiation.

 In this regard, reference may be made to the following non-limiting materials referring to the Table.

No TvPe radiation TvPe glass 639 gamma crystal 1173 gamma Pyrex #
The color or color quality obtained with a tinted pigment applied to the surface or in the mass of the glass, can also be modified with other types of irradiation (eg electron radiation, neutron,
X, etc.). In fact, the color or color quality of the glass can even be modified by irradiation with a cross of various types of radiation, as was the case for some stones (see the materials numbered 0, 165, 239, 1055, 1174, 1658 to 1660, 1667 on the Table).

EXAMPLE 5: Application of colored powders in paper pulp
Tests for applying inorganic pigments according to the invention in the paper pulp were carried out at the Reed company in Quebec City. For this purpose, the pulp used was whitened sulfite commercial pulp (85% white).

 During these tests, the pigment used was reduced to a powder state using a steel pestle and a bronze mortar. A given amount of this powder was added to 5.60 g or 6.70 g of wet paper pulp and up to 500 ml of water was added. The whole was mixed in an industrial mixer and the paste obtained was transformed into a sheet according to the conventional method. The sheet thus obtained was dried at room temperature between two blots held between two metal plates.

All the tests that have been carried out have proved satisfactory. The mineral powders thus tested have in fact made it possible to give interesting colors or qualities of color to the dough. It is thus possible to refer to the following example: N "of the powder Application method Color obtained in Table 1359 1 g with 6.70 g of light orange paper paste
(500 ml of water / blender mixture /
leaf formation at "British
shut machine "/ drying between blots)
This positive result is very interesting for the potential applications that result both in the interior and exterior of the buildings.

 Thus, in the case of interior design, the mineral powders according to the invention could be used for the manufacture of wallpaper or the coloring of arborite or formica prepared from colored paper. This could have interesting implications for the interior design of buildings (wall panels, kitchen counters, furniture, wall cladding, etc.).

 In the case of exterior landscaping, the mineral nature and the non-vulnerability to the solar rays of most of the powders according to the invention could also make possible the use of colored paper products such as arborite, which has never been done so far.

EXAMPLE 6: Application of colored powders in the
enamel paint
Mineral powders according to the invention have been tested as pigments in opaque white enamel paint for metal for domestic use.

 For this purpose, predetermined amounts of 0.25 g, 1 g, 1.50 g and 2 g of several mineral powders were successively applied in 1 cc of opaque white metal paint for domestic use, or white and transparent white paint opaque for car bodywork (Supermaxs P-875 and P-002).

 The pigments were manually ground with the paint. using a frosted glass dial on a frosted glass plate. The paint was applied with a paintbrush on 5 "x 5" metal pieces.

 These tests have all been positive regardless of the powder used, and have shown that the use in "normal" amounts of these powders does not affect the adhesion, the viscosity or the drying rate of the paint.

 Sunlight resistance tests were also carried out. For this purpose, samples were exposed in a window at the top of a two-storey house facing south. These samples were stuck on a cardboard and covered with ordinary glass. The duration of exposure was more than 10 months (from December 3, 1989 to October 15, 1990).

No. of the powder Preparation of the Color obtained Color obtained in the Painting Table after the exhibition
preparation 1141 1 g + 1 cc salmon beige salmon beige
white / opaque / clear more accentuated (tone
manual / orange grinding more
application to pronouncement)
brush [after exposure] 1 1 50 .50 g + 1 cc chamois rosé chamois (rosé tone
opaque white / (light gray tone) purple) a little
manual / lighter grinding
application to [after
paint brush]
These tests of resistance showed that the color of the majority of the samples is accentuated, during the exposure to solar radiation. This reaction corresponds completely to that obtained during the irradiation of inorganic pigments to gamma radiation: the color is accentuated instead of fading as it does with the majority of pigments currently used.

 Irradiation tests on parts painted with enamel paint for self stained with powders according to the invention were furthermore carried out.

 These pieces were irradiated at the Canadian Radiation Center at the Armand Frappier Institute in a UC-15 calibrator.

 Several samples of the same coin were irradiated successively according to various intensities, in order to establish a range of colors or qualities of colors and to try to determine the transformation thresholds. The different doses applied were: 3.3; 5; 7.54; 10; 11.31; 15.08; 18.85; 57.4; 102.4; 201.6; 247.6 and 360 Mrad.

 The color and color quality of a clear, transparent white and opaque white enamel paint can be transformed by irradiation with gamma radiation. It follows that the color of a manufactured and painted object can be modified by this type of irradiation.

 We also note that the color of the enamel paint evolves according to the degree of irradiation. Thus, one can produce a range of colors or qualities of the same color, from the same mineral pigment.

Conclusion
As can thus be appreciated, the colored powders according to the invention can be used as pigments in a very large number of fields.

In addition to the above exemplified applications, numerous other application tests have been successfully carried out on materials as diverse as inks (especially those used in screen printing), stone, porcelain, ceramics, latex paint , metallic coatings, etc.

 This therefore confirms that the present invention provides a complete system of colors which, because of their mineral nature, are particularly suitable for coloring modern architectural materials.

 Of course, various modifications could be made to the color system as well as to the methods of preparation and methods of application which have just been described without departing from the scope of the present invention.

BOARD
Scale of values
Kodak Crey Scale: See Figure in appendix.

Degree of white or black: See Figure in appendix Saturation Peer
This scale of values is hybrid, in the sense that both aspects (its
turation and proximity of white / black) rub shoulders with, and sometimes overlap
in the description of the colors.

Legend:
"Way":
This designation, at the center of the scale of values, applies either to
degree. saturation, either at the degree of proximity with the white / black, or
both. This notion is understandable only in the context of
tions, which precede and follow it.

Color:
In the system, when the color is designated only by its denomi
nation (eg blue), regardless of any qualifier (eg light blue),
it is saturated to the point of our identical to itself, nor
no more and no less.

Tone:
Applies to color, which is not the main one, but who accom-
loincloth. There may be several tones more or less important.

Reflection:
Designates a luminosity, like a colored vapor, which is reflected weakly
with color and tones.

List of natural minerals
Legend: 3) name of the mineral; (b) stone color; c) color å
The state of powder; (d) place of provenance.

&Num; 1. a) actinote b) coniferous green cold and clear c) light gray (light)
green tone) d) erratic block found at Saint-Philémon, Quebec # 2,, a) agate b) dark green lawn c) light gray (slight green tone)
d) Maria, Gaspésie, Quebec # 3. a) amazonite b) turquoise accented c) white (turquoise reflection)
d) Sairs Lake, Abitibi, Quebec & 4. a) amethyst b) violet c) light lilac gray d) Thunderbay,
Ontario, Canada & 5. a) asbestos b) dark gray (green reflection) c) light gray (green reflection)
d) Asbestos Corporation Ltd., Thetford-les-Mines, Quebec a) asbestos or crocidolite b) dark gray blue c) blue gray
pale d) Griqualand, South Africa & num. 7. have massive asbestos b) pale yellow green and yellow very pale green
d) Canadian Refractories Mine, Kilmar, Quebec 8. a) anaicime b) white (gray reflection) c) light gray d) career
De-Mix, Mont Saint-Hilaire, Quebec # 9. a) andalusite b) light brown gray c) light gray d) Bimbowrie,
Australia # 10. a) anorthosite b) light gray c) very, very light gray beige
d) Oka, Quebec & 11. a) anorthosite b) gray made c) medium gray d) Jonquière, Quebec 12. a) apophyllite b) white c) white d) Gaspé Copper Mine, Gaspé,
Québec # 13. a) clay b) light gray green c) light gray green d) Miguasha,
Gaspésie, Quebec & num. a) baryte b) white rosé c) white d) Niobec mine, Saint-Honoré,
Quebec City # 15. a) bauxite c) rosy beige d) French Guiana 16. a) titanium dioxide c) white d) NL Chem Canada Inc., Quebec # 17. a) bornite b) red brown c) red brown d) Lac Musset, Quebec 18. a) calcite c) white d) Compagnie Calcite du Nord, Saint-Eugène
of Mistassini, Quebec ii9. a) calcite b) very light cream yellow ci white d) De-Mix career,
Pontiac, Quebec & num. 20. a) fluorescent calcite b) white (gray reflection) c) white (reflection
yellow) d) Bancroft, Ontario, Canada &21; a) cerite b) dark gray gray c) light gray (light brown)
(d) Jamestown, Colorado, United States, 22. a) chalcocite b) dark iron gray c) dark iron gray d) Butte,
Montana, USA 23. a) chalcopyrite c) dark gray illegate your green) d) Center of
Noranda Mines Research, Montreal, Quebec & N. 24. a) chalcopyrite b) brass yellow, with metallic luster
dark gray d) Hine Noranda, Noranda, Suber & 25. a) coal b) black c) black (brown tone) d) bank of the Saint River
Laurent, Quebec, Quebec & Num. a) chrome c) light gray, with metallic luster 27. a) chromite b) dark gray c) dark gray d) Black Lake, Quebec 28. a) chrysocole b) light turquoise green c) very light turquoise green
(d) Mexico, 29. a) cement c) medium cold gray d) Union of Quarries, Limoilou,
Quebec & num 30. at; copper concentrate (Cu-FeS) c) medium chocolate brown (gray tone)
d) Noranda Mining Research Center, Montreal, Quebec & Num. a) zinc concentrate (ZnO-Fe0) (SO4) c) red brown d) Zinc
Electrolytic of Canada # 32. a) corundum b) medium gray c) light gray d) Transvaal, Africa ai, a; cryolite b) white c) white d) Ivigtut, Groeniand 34. have copper b red brown c) red brown d) unknown 35. a) diopside b) light gray c) beige ciair d) Mont-Orford, Quebec &36; a) dolomite b) light gray c) light gray d) Shefferville, Quebec 37. a) massive epidote b) green brown c) green brown d) James Bay,
Québec * 38. a) Erythrin b) Pink lilac accented c) Light lilac pink
d) Quatemala # 39. a) feldspar b) white c) white d) Baraute, Abitibi, Quebec 40. a) fluorine b) colorless c) colorless d) Ohio, USA 41. a) fluorite b) very pale yellow c) white (slight yellowish reflection
(d) Ohio, United States, 42. a) fluorite b) green still very clear igenre green cold mint3
c) very light gray d) Rogers Mine, Madoc, Ontario, Canada * 43. a) luorine b) red violet c) very light gray d) Ohio,
United States # 44. a) fluorite b) purple and white c) very light gray d) Company
St. Lawrence Fluorspar, Terre-Nauve, Canada & num. a) fluorite b) very light yellow c) white (light yellow)
(d) St. Lawrence Fluorspar., Newfoundland, Canada 46. a) fluorite b) white, pink) c) white, gray)
d) St. Lawrence Company Fluorspar, Newfoundland, Canada * 47. at! fluorite b) pale lilac gray c) pale gray (slight lilac tone)
d) St. Lawrence Company Fluorspar, Newfoundland, Canada i48. a) fluorine b) pink lilac c) very light gray (lilac tone)
d) St. Lawrence Company Fluorspar, Newfoundland, Canada * 49. a) fluorite b) light pink c) white (light pink reflection)
d) St. Lawrence Fluorspar Company, Newfoundland, Canada & num. a) galena b) dark gray, with a metallic luster and dark gray,
metallic luster d) Trail, British Columbia, Canada * 51. a) biotite gneiss b) black-gray, with golden vitreous luster
c) gray fancied d) Abitibi, Quebec # 52. a) granite gneiss b) red beige c) medium pink (light tone
brown) d) Lac Beauport, Quebec & 53. a) goethite c) rust orange dl Red Mill, Quebec 54. (a) graphite (b) dark gray, with metallic luster (c) dark gray, with
metallic luster dl Grenaille, Quebec &55; a) garnet almandine b) red dark brown c) red brown medium
Gore Mountain, New York, United States. a) sandstone b) medium pinkish brown (slight violet tone) c) medium pinkish brown
(light purple tone) d) Percésie, Québec & num. 57. a) halite b) colorless c) colorless d) Seieine Mine, iles-de-la-
Madeleine, Quebec & num. a) hematite c) dark red brown d) Red Mill, Quebec &59; a) hypersthene b) black c) medium brown gray d) Lac Saint-Jean,
Quebec City # 60. a) jade b) deep orange red c) red orange d) China # 61. a) Bi-black-gray and medium-gray labrador d) Lac Saint-Jean, Quebec 62. a) magnetite b) dark gray, metallic luster c) dark gray
d) Labrador Trough, Quebec ióa. a) malachite b) mint green accented c) light mint green
d) Research Center, Noranda Mines, Nontréal Quebec & Num. a) Malachite b) Ribbon variety of mint green accented green
light and bright mint d) air, nfrique # 65. a) mica b) golden brown, vitreous luster c) light amber, luster
glassy d) Hincks, Quebec &# 66. a) microcline b) white (gray reflection) c) white (gray reflection)
d) Buckingham, Quebec &# 67. have molybdenite b) medium gray, with metallic luster c) medium gray,
metallic luster d) Anglo American Mine, Lamotte, Quebec & No. 68. a) nickel c) dark brown gray, with metallic luster d) unknown 69. a) obsidian or volcanic glass b) very dark smoke gray, almost
black c) light gray d) Arkansas, USA 70. a) ocher c) orange d) Saint-Fabien-de-Panet, Quebec & 71. a) olivine b) light gray c) very light gray d) Mont Albert,
Gaspésie 72. a) gold b) golden yellow, metallic luster c) Abitibi, Quebec & num. 73. a) orpiment b) bright orange-yellow c) bright orange-yellow d) Nevada,
United States # 74. a) orthoclase b) light pinkish beige c) very light beige d) close mine
of Buckingham, Quebec & Number 75. a) iron oxide c) black d) Red Mill, Quebec * 76. a) zirconium ore c) light beige d) Tam Ceramic Inc., Quebec 77. a) pitchblende b) medium brown chocolate (burgundy red tone) ci brown
medium milk chocolate d) Yeilowknife, Canada 78. a) pentlandite b) dark iron gray, with silver metallic luster and
golden yellow c) dark iron gray d) Inco Company, Sudbury, Canada 79. a) peridotite b) medium gray c) medium brown gray (green reflection)
d) Thetford-les-Mines, Quebec & num. a) pyrochlore c) red brown d) De-Mix quarry, have Saint
Hilaire, Quebec & Number 81. a) pyrolusite b) black (light brown tone) c) black (light brown tone)
d) probably Nova Scotia 82. a) pyrrhotite b) dark gray brown, with gold-yellow metallic luster
c) dark gray d) Inco Company, Sudbury, Canada 83. a) nickel pyrrhotite b) dark iron gray, with metallic luster
silver and yellow gold c) dark iron gray d) Inco Company, Sudbury,
Canada # 84. a) crystalline quartz b) colorless d) Bonsecours, Quebec 85. a) quartz b) light pink c) very light gray d) unknown 86. a) Shale (Siliery Formation) b) Medium Brown Red (purple tone)
c) light reddish brown (purple tone) d) Cape Rougie, Quebec & num. at; shale (Silllery formation) b) red brown c) pinkish brown
(d) Berthier-Sur-Mer, Quebec & Number 88. a) sericite schist b) light gray (green refiet) c) very, very gray
clear d) Magog, Quebec * 89. a) selenium c) dark gray, @ metallic luster d) Oranda minerals
Inc., Montreal, Quebec * 90. at! serandite b) beige (light orange pink) c) light pink
d) De-Mix quarry, Mont Saint-Hilaire, Quebec J9l. a) serpentine b) yellow green c) light green yellow d) Thetford-les
Mines, Quebec & Number 92. a) sidérose bi brown caramel (gray tone) c) light orange beige
d) De-Mix quarry, Mont Saint-Hilaire, Quebec &# 93. a) zirconium silicate c) very light white yellow reflection)
d) Siai Company, Montreal, Quebec & Number 94. a) silica c) very light gray d) Saint-Urbain, Quebec 95. a) smaltine b) dark gray, metallic luster silver c) gray
dark d) Cobait, Canada 96. a) sodalite b) light cold blue c) light gray (light blue)
d) Bancroft, Canada 97. a) sodalite b) indigo blue c) light gray light blue)
d) possibly Africa 98. a) sulfur b) bright yellow c) bright yellow d) unknown 99. a) spodumene b) green p @ le c) light gray d) Québec Lithium
Company, Baraute, Quebec 100. a) steatite b) cold light gray; sticks measuring 1/2 "x 4 7/8"
1/8 "c) light gray d) East Broughton, Quebec 101. a) steatite b) light coniferous green c) white d) East Broughton,
Québec 102. a) stibine b) dark gray, with silver and blue metallic luster
c) dark gray d) Consolidated Durham Mine, St. George, Canada 103. a) cobalt sulphide b) dark gray, with a metallic sheen c) gray
dark, metallic luster d) Cobalt, Canada 104. a) nickel sulphide b) dark gray c) dark gray d) Sudbury,
Canada 105. a) sylvite b) colorless c) colorless d) Strassfurt, Germany 106. a) tellurium c) dark gray, metallic luster d) Minerals
Noranda Inc., Montreal, Quebec 107. a) tremolite b) medium brown (green conifer) c) gray beige
(d) Tetreault Mine, Montauban, Quebec 108. (a) vesuvianite (b) lilac (c) lilac (d) John Mansville Mine,
Asbestos, Quebec 109. a) wilsonite (local variety of scapolite or wernerite) b) gray
violet c) light lilac gray d) Tetreault Mine, Montauban, Quebec 110. a) yofornerite b) dark chocolate brown c) dark chocolate brown
d) De-Mix quarry, Mont Saint-Hilaire, Quebec 111. a zinc c) medium gray, metallic luster 112. a) incite red b) 2 zones: dark gray / orange red c) brown
medium milk chocolate (red tone) d) Franklin, New Jersey,
United States 113. a) calcite b) light pink c) rosy white d) Pontiac, Quebec
List of abbreviations, formulas and symbols cc: cubic centimeter (s) K2CO3: potassium carbonate cm2: square cannter (s) KON: potassium cyanide g: gram (s) H2SO4: sulfuric acid h: hour (s) H3PO4: humic phosphoric acid: wet NaCl: sodium chloride
J: Joule (s) HF: fluorhydrochloride j: day (s) NH4OH: ammonia km: kilometer (s) #: number kV: kilovolt (s) ": inch (s) min: minute (s) è: gamma
Mrad: Megarad HNO3: nitric acid ml: millilit (s) to:
St.: Saint NaOH; dry caustic soda: second (s) F: fahrenheit ses .: week (s) HCl: hydrochloric acid
UV: ultraviolet C: Centigrade W: Watt (s) Na2CO3: sodium carbonate
Ca (OH) 2: calcium hydroxide
MgO: magnesium oxide
SiC: silicon carbide
SYSTEM OF MINERAL COLORS AND APPEARED TONES;
ITS APPLICATION IN MODERN ARCHITECTURAL MATERIALS color obtained mineral number / production process
mineral: # 83 / production process: a) white 1 0 # 1037 C: 1 g + H3PO4 80 ml / soaking: b) gray green 2 wk. / drying on a hot plate (hum.)
/ color of a) solid b) liquid
mineral: * 101 I production process: a) white 2 0 # 1204 C: 2 g + H3PO4 50 ml / soaking: b) black 2 wk. / drying on a hot plate (hum.)

deposit in an oven / 0 # 1000 C / chill
slow in the oven
mineral: # 89 / production method: transparent white 12 2 independent masses of 150 g dough
glass (sodalime) are collected in the state of
melting (1200 C) in the furnace, out of two
independent metal rods / 2 g of selenium
are sprinkled on the surface of a single face
from one of the collections, which is covered by
the other collection, trapping the pigment in
sandwich / then everything is reintroduced into
the furnace and remelted to the flame has
1200 C to make a whole i then, collecting
resultant is detached from the metal rods
/ deposit of this collection on a plate of
ceramic biscuit in a furnace in atmosphere
normal of 0 # 1000 C / we turn off the oven /
the glass cools there up to 0 C
mineral: # 98 / production process: very white 13 1 g is sprinkled on 150 g of crystalline glass paste (sodalime), which was collected in the state of
melting in the furnace (1200 C) on a
metal rod / then, the whole thing is reintroduced
in the furnace and fade to
1200 C / then, the collection is detached from
mineral: 113 / production process: a) white 14 4 g + H3PO4 20 ml i soaking: 3 d / drying: b) amber brown on hot plate (hum.) / color of
a) solid b) liquid
mineral: # 48 / production method: a) white 15 2 g + H3PO4 20 ml / soaking: 3 d / drying b) chocolate brown on hot plate (hum.) / color of
a) liquid b) solid
mineral: i98 / production process: milky white 16 1 g + S g pyrex I manual grinding I heated
fage: 5 C per min of 011245 OC + hold
during 1 hi cooling: 5 C per min
to the ambient air / all in atmosphere
natural air
mineral: * 36 I production process: white 17 2 g + H3PO4 20 ml / soaking: 3 d / drying
on hot plate (hum.)
mineral: # 65 / production process: white 18 4 g + H3PO4 50 ml / soaking: 4 wk. / drying
on hot plate (hum.)
mineral: # 74 / production method: white 19 2 g + H3PO4 20 ml / soaking: 3 d / drying
on hot plate (hum.)
mineral: # 88 / production method: white 20 2 g + H3PO4 20 ml / soaking: 3 d / drying
on hot plate (hum.)
mineral: 19 production process: milky white 21 4 g + H3PO4 40 ml i soaking: 1 wk. / brown reflection drying) on hotplate (hum.)
mineral: # 5 I production process: ivory iton 22 3g + 1cc transjaune white printing ink) parent / mechanical grinding / 1 printing on
glossy white paper / irradiated with radiation
# to 22.8 Mrad
mineral: 15 / production process: very light cream 23 3 g + HCl 25 ml / soaking: 5 d / drying on
hot plate: 1 g + 1 cc of printer ink
transparent white merie i mechanical grinding J
printing on glossy / irradiated white paper
at radiation # at 22.8 Mrad
mineral: # 5 / production method: clear cream 24 3 g + HF 20 ml / soaking: 24 hf drying in
an oven at 37 C: .50 g + 1 cc im ink
transparent white primery i manual grinding /
1 print on glossy / irradiated white paper
at radiation # at 11.4 Mrad
mineral: # 106 I production method: clear cream 150 g of glass paste (sodalime) is collected and milky in the furnace (1200 C)
on a metal rod / 1 g of tellurium is
sprinkled on the surface of the glass / everything is
reintroduced into the furnace and melted to the
flame at 1200 C / then, the collection is de
stained with metal rod
minerals: # 5 + # 16 + # 98 / production process: light cream 26 .50 g + .50 g + .50 gi 871 C / 1 h
mineral: # 5 / production process: cream 27 3 g + H2SO4 20 ml f soaking: 24 h / drying
on hot plate: .50 g + 1 cc ink
transparent white printing machine I grinding manu
el i 1 print on glossy white paper i ir
radiation radiation at 11.4 Mrad
mineral: # 5 i production process: orange cream 28 50 g + HCl 200 mi or asbestos completely re
covered with HCl X dipping: 1 wk. i drying
on a hot plate: .50 g + Na2CO3 .50 g
+ HNOs 40 ml / soaking: 5 days separation from
liquid and solid i drying on bath of
sand / liquid is irradiated with radiation
# to 64.7 Mrad
mineral: # 67 / production process: cream (green tones 29 powder finely ground and heated from and gray; 01537 C: .50 g + H2SO4 15 ml / soaking:
2 d / slow drying on a hot plate: .15
g + 6 cc concrete polymer + 0.18 cc cata
lyseur + 1.5 thousandth of g cobalt 6% + 2 g
Portland cement i manual grinding / molding
/ curing irradiated with radiation? at
18.85 Mrad
mineral: # 67 / production process: dark cream (tones 30 finely ground and heated powder of green and gray) 0 # 760 C: 4 g + H3PO4 20 ml / soaking:
3 days drying on a hot plate
mineral: # 106 / production method: gray cream and 31 the rounded part of a test tube made of milky pyrex is brought to the state of fusion with a torch
oxyacetylinic then 5 g of tellurium is
sprinkled on the molten surface / all
is immediately returned to the state of fusion
with the torch / air cooling
ambient is immediate
mineral: # 6 / production process: cream gray (light 32 4 g + HCl 100 ml / soaking: 2 weeks i drying brown) on hot plate: .50 g + 1 cc ink
transparent white printing machine / comminuting
print on glossy white paper
/ irradiated with radiation # at 17.91 Mrad
minerals: 4 + # 98 i production process: very light lilac 33 2 g + 2 g / 704 C / 1 h / irradiated to the radius
at # 64.7 Mard
mineral: # 4 / production process: lilac more pro 34 1000 C / 1 h / powder irradiated with radiation nounced as the # to 122.984 Mrad lilac clear
mineral: # 47 / production method: lilac 35 1000 C / 1 hi radiation irradiated powder
# to 64.7 Mrad
mineral: # 47 / production method: pronounced lilac 36 1000 C / 1 h / radiation irradiated powder
# to 64.7 Mrad
mineral: 44 / production method: very pink lilac, 37 2 g + HCl 20 ml / soaking: 3 days / drying on very clear heating plate / irradiated with radiation
electronic at 302,831 rad
mineral: # 44 / production process: pink lilac (tone 38 2 g + HCl 20 ml I soaking: 3 d / drying on gray) very, very hotplate / irradiated with clear radiation # to 64.7 Mrad
mineral: # 44 I production process: very pink lilac, 39 1000 C i 1 h I powder irradiated with very light electron radiation at 302.831 rad
mineral: # 109 / production method: pink lilac 40 3 g + HNO3 100 mi f soaking: 4 years i drying
on hot plate
minerals: 58 ~ # 16 / production process:
1 g # 58 + 2 g # 16: light pink lilac 41 0 # 704 oC (very light gray tone) # pink lilac more 42 0 # 926 C dark
mineral: # 44 / production method: medium pink lilac 43 1000 C; ih / radiation irradiated powder (slight reflection # at 482.984 gray Mrad)
minerals: # 53 + # 16 / production process:
- .50 g # 53 + 1.50 g # 16: clear lilac 44 ut 260 OC that will verc 45 0 # 537 OC the 4. lilac (red tone) 46 0 # 648 C more intense 47 Ot 704 C
- 1 g # 53 + 1.50 g # 16: dark lilac 45 Ot 260 OC going to 49 0 # 537 C the dark lilac (tone 50 0 # 648 C red) 51 0 # 704 OC
mineral: 27 / production process: a) gray lilac 52 4 g + H2SO4 100 ml / soaking: 4 years / clear drying b) gray on hot plate / coulaur a) liquid or dark brown b) solid
minerals: # 98 + 4 production process: dark gray lilac 53 2 g + 2 g / 704 C / 1 h / irradiated (pinkish reflection) with radiation at 424.7 Mrad
mineral: # 95 / production method: pink lilac very 54 0tl037 C: .30 g + HN03 50 ml I soaking: 2 pronounced; green sem. i drying on hotplate I irradiated dark lawn with radiation # at 424.7 Mrad
mineral: # 95 / production method: pink lilac plus 55 3 g + HCl 80 ml / soaking: 2 w. / separation and acceleration of the liquid and solid i drying on killed i green lawn heating plate i the liquid is irradiated more intense and radiation # at 424.7 Mrad accented
mineral: # 38 production process: light purple 56 232 oC / 10 min
minerals: # 63 + # 16 / production process: pastel violet 57 .50 g # 53 + 1 g # 16/0 # 760 C pronounced
mineral: # 53; production process:
0 # 1093 C: purple plus 57.1 1 g + .25 9 soot oil i oil
grinding e plus, 57.2 ig + .50 g soapy oil i # black grinding 57.3 1 g + 1 g soaked oil of oil / grinding
mineral: # 40 / production process: purple 58 1 gti cc white synthetic enamel paint
transparent for auto / manual grinding / ap
on a piece of body sheet
measuring 1 "x 1" / irradiated with radiation #
at 360 Mrad
mineral: # 44 / production process: dark purple violet 59 stone completely covered with HCl 20 ml! as the purple soaking: 2 wk. / irradiated with radiation
# to 5.7 Mrad / drying on sand bath
minerals: * 48 ~ 98! production process: very violet 60 2g + 2g / 704C / 1h / irradiated with accented radiation # to 424.7 Mrad
mineral: * 41 i production process: very violet 61 815 C / 1 h / irradiated stone with intense radiation # at 64.7 Mrad
mineral: # 49 / production process: violet plus 62 1000 C / 1 h / irradiated powder with intense radiation # at 122.984 Mrad
mineral: # 41 / production process: dark purple 63 'g + 1 cc white synthetic enamel paint and clear accented for auto / manual grinding / ap-
on a piece of body sheet
measuring 1 "x 1" / radiation irradiated # to
7.54 Mrad
mineral: T7 / production process: dark purple 64 1g + 1cc white synthetic enamel paint
transparent for auto / manual grinding / ap
on a piece of body sheet
measuring 1 "x 1" / radiation irradiated # to
57.4 Mrad
mineral: # 47 / production method: dark purple 65 2 g + HCl 20 ml i soaking: 3; / drying on
hotplate / radiation irradiated #
at 18.85 Mrad
mineral: # 47 / production method: dark violet 66 2 g + NHO3 20 ml / soaking: 3 d / drying on
hotplate / radiation irradiated # to
18.85 Mrad
mineral: # 49 / production process:
dark violet 67 2 g + HNO3 20 ml / soaking: 3 d / drying on
hotplate / radiation irradiated # to
18.85 Mrad
mineral: # 41 I production process:
dark purple 68 5 g stones + 13.74 gg Portland cement +
# 6.50 cc water mixing J molding / hardening
# to radiation # to 18.85 Mrad / color of
1 very dark purple stones 69 5 g stones + 13.74 9 Portland cement
+ 6.50 cc water / mixing / molding / hardened
f 0 # 704 oC / cooling / irradiated
at radiation # at 18.85 Mrad / color of
stone
mineral: F75 f production process: dark violet and 70 10 g + 10 g NaCl / 0 # 926 C / slow cooling in the oven
mineral: # 95 I production process: dark violet 71 0 # 1037 C: .30 g + HCl 50 ml / soaking: 2
wk. / separation of liquid and solid
liquid, dried in powder form, is heated
on a hotplate of 0 # 371 C
mineral: # 48 i production process: very dark purple 72 stone covered with paste i 871 C / 1 h and saturated irradiated with radiation w at 424.7 Mrad
mineral: # 41 / production process:
1 g + 1 cc white synthetic enamel paint
transparent for auto f manual grinding i ap
on a piece of body sheet
measuring 1 ": 1 / irradiated with radiation i medium pink violet 73 10 Mrad # purple bright red 74 57.4 Mrad
mineral: # 40 f production process:
red violet 75 815 C / 1 h / rayon irradiated stone
ment # to 424.7 Mrad
mineral: * 41 t production process: purple red 76 5 g stones + 13.74 g Portland cement +
6.50 c water mixing / molding f harden
radiation irradiation # at 18.85 Mr ad
/ color of stones
minerals: # 44 + # 98 f production process: violet red 77 2 g + 2 gi 704 CJ 'hi irradiated medium (gray tone) with radiation # at 424.7 Mrad
mineral: # 110 / production method: a) bright red violet 78 0 # 871 C: .20 g + H3PO4 100 ml / tremb) dark brown page: 4 years / hot plate drying
(hum.) / color of a) liquid b) sclide
mineral: # 81 / production method: very red violet 79 1 g + 5 g glass powder (spruce pine batch) pronounced / manual grinding / deposit on a plate of
ceramic biscuit / heating in
oven of 0 # 1000 gold in normal atmosphere;
slow cooling on the tower a little darker 80 radiation irradiation # at 9.88 Mrad
mineral: # 48 / production process: very red violet 81 1000 C / 1 h / irradiated powder with pronounced radiation # at 424.7 Mrad
mineral: # 41 / production process: very red red 82 stone irradiated with electron radiation to pronounced 155,082 rad, then to radiation # to 148,4
mrad
mineral: # 47 / production process:
very red violet 83 1000 C / 1 h / irradiated powder with pronounced radiation # at 424.7 Mrad
mineral: # 47 / production method: dark red violet 84 2 g + 20 ml ether / natural / irradiated drying
radiation at 18.85 Mrad
mineral: # 47 / production method: dark red violet 85 2 g + NH4OH 20 ml / natural / irradiated drying
radiation at 18.85 Mrad
mineral: # 41! production process: very red violet 86 815 C / 1 h / irradiated stone with dark radiation # to 424.7 Mrad
mineral: # 42 / production process: purple red e7 5 g stones + 13.74 g Portland cement + 6.50 shade c water / mixing / molding i curing J
0 # 1037 C f cooling / irradiated at
radiation i at 18.85 Mrad / color: stones
Minerals: # 18 + # 53 / Production Process:
# 53 0 # 1093 C purpurin purple 88 1 g # 53 + .50 g # 18 / grinding # violet purpurin 89 1 g # 53 + 1.50 g # 18 / grinding very, very clear
mineral: # 109 / production method: purpurin violet 90 irradiated with radiation # at 242,804 Mrad
mineral: # 81 / production method: a) violet purpurin 91 110 g + H3PO4 150 ml / soaking: 2 wk. / sá b) violet purpurin liquid and solid partion / drying on more intense and liquid 1r heating plate / dark recovery c) residual solid black and addition of H3PO4 150 ml /
soaking: 1 week / boiling on a plate
heating during 2 / separation of the 2nd li
quide and solid J drying on heating plate
fante (hum.) / color of a) 1st liquor b) 2nd
liquid c) solid
mineral: # 81 / production process: a) violet purpurin 92 1000 C / 12 h: 60 g + H3PO4 200 ml / intense deposit b) old immediately on hot plate I pink boiling (lilac tone) for 2 days / separation from liquid and plum) black brown (lide tone / drying on heating plate (hum.) / purple accentuated) color of a) 1st liquid b) 2nd liquid
c) solid
Minerals: # 98 + # 43 / production method: brown violet 93 1 g + 1 g / 926 C / 1 h / irradiated to the radius
nement # at 425.65 Mrad
Minerals: # 98 + # 41 / production method: brown purple 94 1 g + 1 g / 926 C / 1 h / irradiated at
radiation at 425.65 Mrad
mineral: # 98 + # 42 / production method: dark brown violet 95 í g + 1 g / 926 C / 1 h I irradiated
radiation i at 425.65 t4rad
Minerals: # 98 + # 53 / Production Process:
# 53 0 # 760 C: dark brown purple 96 2 g # 53 + 2 g # 98/871 C / 1 h dark purple (tone 97 2 g # 53 + 6 g # 98/871 C / I h dark brown) # dark purple (tone 98 2 g # + 12 g # 98/871 C / 1 h brown + accentuated) # dark purple (tone 99 2 g # 53 + 24 g # 98/871 C / 1h brown + accented)
mineral: # 43 / production method: very gray violet 100 815 C / 1 h / irradiated with intense radiation # at 424.7 Mrad
mineral: # 43 I production process: dark gray purple 101 1 g + 1 cc white synthetic enamel paint
transparent for auto i manual grinding; ap
on a piece of sheet metal body
measuring 1 "x 1" / radiation irradiated
# to 36 Mrad
Minerals: # 98 + # 4 / Production Process: Purpurin Purple 102 2 g + 2 g / 704 C / 1 hr / irradiated with flash / gray violet electronically at 302,831 rad
mineral: # 95 / production method: violet / purple 103 3 g + H3PO4 80 ml / soaking: 2 wk. / sé white chage on hot plate (hum.)
mineral: # 40 / production process: blue violet 104 stone irradiated with electronic radiation at
155,082 rad and radiation at 148.4 Mrad
mineral: # 41 / production process: purple blue 105 1g + 1cc paint enamel synthetic blac
transparent for auto / manual grinding / ap
on a piece of body sheet
measuring 1 "x 1" / radiation irradiated # to
360 Mrad
minerals: # 48 + # 98 / production method: medium blue violet 106 2 g + 2 g / 704 C / 1 h / irradiated
radiation at 64.7 Mrad
mineral: # 95 / production process: dark blue violet 107 0 # 1037 C: .30 g + HCl 50 ml / soaking: 2
wk. / separation of liquid and solid /
drying on hotplate / irradiated at
radiation at 64.7 Mrad
mineral: # 8 / production process:
2 g + Na2CO3 2 g: violet blue (tone 108 0 # 982 C + 1 h at 982 C red) 109 0 # 1037 C + 1 h at 1037 C
mineral: 41 / production process: violet blue (tone 110 stone irradiated with electronic radiation to red) very 164,800 rad, then radiation # at 148.4 saturated Mrad
mineral: # 57 / production method: violet blue 111 2 g + Na2CO3 2 g / 0 # 593 C + 1 h at 593 C / (gray reflection) irradiated with radiation # at 424.7 Mrad
minerals: # 73 + # 38 / production process: purple blue 112 1 g + 1 g / 232 C / 10 min
mineral: # 38 / production method: purple blue 113 1 g + 1 g animal bone soot / 232 C / 10 min
Minerals: # 87 + 38 / Production Process: Purple 114 1g + 1 g / 232 C / 10 min
Minerals: # 111 + # 38 / Production Method: Purple 115 1g + 1 g / 232 C / 10 min
minerals: # 58 + # 8 / production process: purple blue 116 1g + 1 g / 232 C / 10 min
mineral: # 34 / production process: violet blue 117 100 g + NHO3 100 ml / soaking: 5 m. / drying
natural: 4 g + NH4OH 20 ml / natural drying
Minerals: # 41 + # 98 / production method: blue violet 118 1g + 1g / 926 C / 1 h / irradiated to the radius
at 65.65 Mrad
minerals: # 42 + # 98 / production method: blue violet 119 1 g + 1 g / 926 C / 1 h / irradiated to the radius
at 65.65 Mrad
mineral: 97 / production process: intense blue blue 120 stone irradiated with radiation @ at 482.984 and deep Mrad
mineral: # 97 / production process: very violet blue 121 815 C / 1 h / irradiated stone with intense radiation @ at 424.7 Mrad
mineral: # 14 / production method: very violet blue 122 0 @ 1093 C / irradiated powder with intense radiation @ 64.7 Mrad
mineral: # 38 / production method: dark violet blue 123 1 g + 5 g pyrex / manual grinding / heating [green zones: 5 C per minute from 0 @ 1245 C + holding for 1 hour / cooling: 5 C per min juice
only in the ambient air / all in atmosphere
darker natural air 124 radiation irradiation @ at 4.94 Mrad
mineral: 95 / production method: dark purple blue 125 2 g + Na2CO3 2.50 g / 1037 C / 1 h
mineral: # 67 / production process: a) very dark blue 126 peat-coated stone / 871 C / 30 min: and very intense off-peak and covered with HNO3 80 ml (purple reflection) / soaking: 1 wk. / hot plate deposit b) fante gray / boiling point up to
complete drying / pouring of a) liquid
b) solid
mineral: # 22 / production process: a) very light blue 127 0 @ 1037 C: 1 g + H2SO4 50 ml / soaking: 2 b) mint green min. / separation of liquid and solid / clear (blue tone) drying on hotplate / color of
a) liquid b) solid
mineral: 28 / production process: very light blue 128 2 g + H3PO4 20 ml / soaking: 3 d / drying
on hot plate (hum.)
mineral: # 30 / production method: a) light blue 129 4 g + H3PO4 50 ml / soaking: 4 wk. / drying b) dark gray on hotplate (hum.) / color of
a) liquid b) solid
mineral: # 64 / production method: light blue 130 2 g + H3PO4 20 ml / soaking: 3 d / drying
on hot plate (hum.)
mineral: # 67 / production process: intermediate blue between 131 finely ground and heated powder of 0 # 537 C: light blue and .50 g + HNO3 15 ml / soaking: 2 days drying light yellow slow on hot plate # light blue 132 finely ground and heated powder of 0 # 593 OC:
.50 g + HNO3 15 ml i soaking: 2 days drying
slow on hot plate
mineral: # 95 / production process: pastel blue (under 133 0 # 1037 C: .60 g + HCl 100 ml / soaking: 4 years a verdigris / drying on iridescent hotplate)
mineral: 28 / production process: a) blue 134 2 g + HNO3 25 ml i separation of liquid and b) mint green
mineral: # 67 i production process: very intense blue 147 3 g of finely ground powder + HNO3 30 ml /
soaking: 3 days / hot plate drying
mineral: # 67 I production process:
very intense blue 148 finely ground + heated powder of 0 # 593 C:
1 .50 g + HCl 15 ml / soaking: 2 days drying
slow on hot plate
very intense blue 149 finely ground + heated powder of 0 # 648 C:
1 .50 g + HCl 15 ml / soaking: 2 days drying
slow on hot plate blue very intense 150 powder finely ground + heated 0 # 704 OC:
.50 g + HCl 15 ml / soaking: 2 days / drying
slow on hot plate
mineral: # 67 / production process: very intense blue 151 finely ground + heated powder of 0 # 482 C:
# .50 g + H2SO4 15 ml I soaking: 2 days drying
slow on very intense blue hot plate 152 finely ground + heated powder of 0t593 OC:
# .50 g + H2SE4 15 ml i soaking: 2 d / drying
slow on hot blue plate very intense 153 powder finely ground + heated 0 # 648 C:
# .50 g + H2S04 15 ml / soaking: 2 days drying
# slow on hot blue plate very intense 154 powder finely ground + heated 0t704 OC:
.50 g + H2SO4 15 ml / soaking: 2 days / drying
slow on hot plate
mineral: # 67 / production process: very intense blue 155 heated stone from Ot 760 C + 6 h to 760 C i
removal of crystals formed on the surface
stone: .30 g of crystals + HNO3 25 ml /
soaking: 2 days drying on a very hot blue hot plate 156 heated stone from 0t760 C + bh to 760 CI
removal of crystals formed on the surface
I of the stone: .30 g of crystals + HNO3 20 ml +
I HCl 5 ml / soaking: 2 days / drying on a plate
I heated very intense blue 157 heated stone from 0 # 760 C + 6 h to 760 C /
1 removal of crystals formed on the surface
stone: .30 g of crystals + HNO3 15 mi +
# HCI 10 ml / soaking: 2 days / drying very intense blue plate 158 heated stone from 01760 C + 6 h to 760 C /
removal of crystals formed on the surface
1 of the stone: .30 g of crystals + HNOx 10 ml +
I HCl 15 ml I soaking: 2 days / drying on plate # heating very intense blue 159 heated stone from 0 # 760 C + 6 h to 760 C /
removal of crystals formed on the surface
stone: .30 g of crystals + HNO3 5 ml +
HCI 20 ml / soaking: 2 days / drying on plate
heating
mineral: # 67 / production process: very intense blue 160 paste-coated stone 1 871 CI 30 min /
cooling / stone is cleared from the
paste and ground: 2 g of powder + HNO3 100 ml /
soaking: 1 week / hot plate deposit
te / entry into boiling, then slow drying
on hot plate
mineral: # 67 / production process: very intense blue 161 stone covered with HNO3 20 ml / soaking: 3
j / drying on a hot plate
mineral: # 99 / method of procudtion: very intense blue 162 2 g + Na2CO3 2 g / 926 C / 1 h
mineral: # 67 / production process: very intense blue 163 3 g of finely ground powder + HNO3 30 ml /
soaking: 3 days / hot plate drying
irradiated with radiation @ 64.7 Mrad
mineral: 95 / production method: dark blue 164 1 g + Na2CO3 1.50 g / 982 C / 1 h
mineral: # 42 / production process: very dark blue, 165 stone irradiated with electron radiation at almost 155,082 rad, then at radiation @ at 360 Mrad black @
mineral: 14 / production process: blue / pink lilac 166 0 @ 1037 C / radiation irradiated @ 64.7
mrad
mineral: # 14 / production method: blue / light pink 167,926 C / radiated irradiation
64.7 Mrad
mineral: 14, process of production; a) blue / black 168 0 # 1037 C: # 30 g + H3PO4 50 ml / soaking: b) white 2 weeks / drying on a hot plate (hum.)
/ color of a) liquid b) solid
mineral: # 42 / production process: indigo blue 169 815 C / 1 h / stone irradiated with radiation
@ at 424.7 Mrad
mineral: # 97 / production process: indigo blue 170 815 C / 1h / stone irradiated with radiation
@ at 64.7 Mard
mineral: # 90 / production process: moiré: blue 171 1 g + 5 g pyrex / manual grinding / heatingdigo / light gray ge: 5 C per min from 0 @ 1245 C + maintenance pen / pale pinkish brown 1 h / cooling: 5 C per minute juice / medium pinkish brown than in ambient air / all in atmosphere
natural air
mineral: # 97 / production process: indigo blue plus 172 irradiated stone @ radiation at 360 Mrad intense and dark as indigo blue
mineral: # 97 I production process: indigo blue plus 173 stone placed for a period of 7 days under irintense and dark radiation, directly at the exit of the beam than the primary indigo blue of an X-ray generator (radia
copper, 20 mA, 40 kV)
mineral: # 64 / production process: intense indigo blue 174 2 g + H2S04 20 ml - natural drying
mineral: # 67 / production process: very indigo blue 175 3 g of finely ground powder + HNO3 30 ml / intense soaking: 3 d / hot plate drying
irradiated with radiation @ 424.7 Mrad
mineral: 967 f production process: dark indigo blue 176 finely ground and heated powder of Ot 593 OC:
.50 g + H2SO4 15 ml / soaking: 2 days / drying
slow on hot plate: .15 g + 6 cc
concrete polymer + 0.18 cc catalyst + 1.50
thousandth of g cobalt 6% J grinding + malaxa
ge manuals / molding / curing / irradia
@ radiation at 18.85 Mrad
mineral: # 96 i production process:
2 g + Na2CO3 2 g: dark indigo blue 177 0 # 815 C + 1 h at 815 C
# 178 0 # 871 C +1 h to 871 C
mineral: # 41 f production process: dark indigo blue 179 stone heated to 65 oC J 2 h I cool
to ambient air / radiation irradiation
@ at 2.26 Mrad
mineral: # 41 / production process: dark indigo blue 180 paste-coated stone 1 65 oC / 2 hi re
ambient air cooling / irradiated
radiation @ at 2.26 Mrad
mineral: 41 / production process: very indigo blue 151 stone coated with paste J 65 C / 2 h / dark deposit immediately at -20 C for 2 h / irradiated with
radiation @ at 2.26 Mrad
mineral: 41 / production process: indigo blue very 182 paste-coated stone / 65 C / 2 hi irrafornced (light weight with radiation at 2.26 Mrad gray)
mineral: # 41 / production process: very indigo blue 123 5 g stones + 13.74 g Portland cement + dark 6.500 cc water mixing / molding / hardening
/ 0 # 1037 C / cooling / irradiated
at radiation # at 18.85 Mrd / color of
stone
mineral: # 42 / protected production: blue cobalt 184 5 g stones + 13.74 g Portland cement +
6.50 cc water mixing i molding / harden
radiation irradiated at 18.85 Mrad /
color of stones
mineral: # 95 / production process: intense cobalt blue 185 lg + 6.50 g glass powder (spruce pine and dark batch) / manual grinding / deposit on a pla
I that ceramic biscuit i heating in a
oven of 0 # 1000 C in normal atmosphere i re
I slow cooling in the furnace l blue cobalt a radiation irradiated 186 # at 2.467 Mrad little darker
mineral: # 41 / production process: prussian blue 187 stone heated to 65 C / 2 h / irradiated to dark the hot state to radiation # to 2.26 Mrad
mineral: # 28 J production process: ultramarine blue 188 2 g + NH40H 20 ml / natural drying
mineral: # 46 / production process: ultramarine blue 189 5 g stones + 13.74 g Portland cement +
6.50 cc water / mixing / molding / hardening
/ 0 # 1093 C / cooling / irradiated
radiation at 18.85 Mrad
mineral: i95 / production process: ultramarine 190 lg + Na2CO3 2.50 g / 982 irradiated ilhi
intense radiation at 64.7 Mrad
mineral: # 41 / production process: dark ultramarine blue 191 stone cooled to -20 C for 2 h / irra
(light violet tone) in the cold state with radiation at 2.26
mrad
mineral: # 41 I production process: deep ultramarine blue 192 stone coated with paste and cooled to -20 ° C
(light purple tone) for 2 h / irradiated in cold
Radiation at 2.26 Mrad
mineral: # 41 / production process: dark ultramarine blue 193 stone is heated to 65 oC / 2 h / deposit im
(light purple tone) mediate at -20 C for 2 h / irradiated in the state
cold radiation at 2.26 Mrad
mineral: # 95 / production process: dark ultramarine blue 194 1 g + 5 g pyrex / manual grinding f heating
(gray tone) age: 5 C per min of 0 # 1245 C + holding pen
I 1 hr J cooling: 5 C per min juice
I to the ambient air / all in atmosphere
i of natural air # ultramarine blue plus 195 irradiated with radiation # at 4.94 Mrd
dark (red reflection)
mineral: 19 / production process: blue a: ur very, 196 1 g + 5 g pyrex / manual grinding / very pale heat ge: 5 C per min of 0t1245 C + maintenance pen
1 hour / cooling: 5 C per minute
that in the ambient air I all in atmosphere
natural air
mineral: # 34 I production process: pale azure 197 stone covered with 1000 ml acetic acid
f natural drying / crystal picking
formed on the surface of the stone: 4 g screaming
rate + NH4OH 20 ml / natural drying
mineral: # 109 / production method: azure clear 198 4 g + K2CO3 1 g / 0 # 815 C
mineral: production method: azur plus 199 2 g + Na2CO3 2 gi 0 # 982 OC + 1 h at 982 C light as the / irradiated with electronic radiation at azure clear 162,431 rad
mineral: # 9 / production method: light blue azure 200 irradiated with radiation # at 65 Mrad: .81 g +
Na2CO3 1.31 g / 926 C / 1 h
mineral: # 22 i production process: light blue azur 201 4 g + H2SO4 100 ml f soaking: 2 wk. i separated
ration of liquid and solid I drying on
hot plate / the liquid is irradiated at
electronic radiation at 162,431 rad
mineral: # 17 J production process: light azure 202 815 C / lh: 1 g + H2SO4 40 ml / soaking:
14 days drying on a hot plate
mineral: i17 / production process: a) light blue azur 203 lg + HNO3 10 ml / soaking: 6 d / separation b) medium apple green of liquid and solid i natural drying f (gray tone) color of a) liquid b ) solid
mineral: # 109 / production process: light azure 204 2 g + K2CO3 1 g / 0 # 871 C
mineral: # 109 i Production method: light azure 205 1 g + Na2CO3 .50 g / 871 C i 1 h # more intense 206 1 g + Na2CO3 1 g / 871 C / 1 h
mineral: # 17 / production process: a) light azure blue 207 1 g + HCl 40 ml / soaking: 6 d / separation and bright b) lime green liquid and solid f natural drying / high (yellow tone) color a) liquid b) solid
mineral: # 17 / production method: a) light azure blue 208 1 g + HNO3 40 ml / soaking: 6 d / separation and very bright b) liquid green and solid I natural drying / phthalo pale separation of liquid and solid color
liquid aj b) solid
mineral: # 34 / production process: azure 209 100 g + HNO3 100 ml / soaking: 5 m. drying
natural: 4 g + 20 ml ether / natural drying
mineral: * 4 / production process:
2 g + Na2CO3 2 g: azure 210 0 # 871 C + 1 h at 871 ° C
# 211 0 # 1037 C + 1 h to 1037 C
mineral: # 109 i production process:
2 g + Na2CO3 2 g: azure 212 0 # 871 C + 2 h at 871 C va I 213 Ot 871 C + 4 h at 871 C Intensifier 214 $ 0 # 871 C + 8 h at 871 ° C
mineral: # 109 / production process:
2 g + Na2CO3 2 g: azure 215 Ot 871 C + lh at 871 C 4 azure 216 0 # 1037 C + 1 h at 1037 C more intense
mineral: # 109 / production process:
2 g + K2CO3 3 9: azure blue tr 8s 217 0 # 815 C
clear blue azure medium 218 0 # 871 C azure blue much 219 0 # 926 C more accentuated 4 azure blue 220 0 # 982 C more intense
mineral: # 109 / production process:
2 g + K2CO3 2 g: light azure blue 221 0 # 871 C medium azure blue 222 0 # 926 C and bright # azure blue a lot 223 0 # @ 982 C more intense
mineral: # 34 / production method: azure blue 224 100 g + HCl 100 ml / soaking: 5 m. drying
on hot plate: 4 g + 20 ml ether /
natural drying
mineral: # 34 f production process: azure plus 225 stone covered with 1000 ml of pale acetic acid as the natural drying / removal of the intense azure crystals formed on the stone: 2 g crystals + 4 g
Portland cement + 6cc water f grinding
manual / molding c hardening / irradiated at
radiation at 18.85 Mrad
mineral: # 34 / production process: intense azure blue 226 stone covered with 1000 ml acetic acid
/ natural drying / crystal picking
trained on the pirre: 4 g of crystals + 20 ml
ether / natural drying
mineral: # 10 / production method: intense azure blue 227 2 g + Na2CO3 2 g / 0 # 815 C + 1 h at 815 C
mineral: # 109 / production process:
2 g + Na2CO3 2 g: powerful azure blue 228 871 C / 1 h more powerful 229 871 C / 3 h still 230 871 C / 6 h 4 and still 231 871 C / 8 h
mineral: 17 production process: a) very blue azur 232 815 C ilh: 1 g + HNO3 40 ml i soaking: powerful and lively 14 i separation of liquid and solid ib) pale green natural drying / color of ) liquid
b) solid
mineral: 64 production process: very blue azur 233 2 g + H2SO4 20 ml / natural drying / irradiated with electronic radiation at 162,431 rad
mineral: 34 production process: very light blue 234 100 g + HCl 100 ml / soaking: 5 m. I drying
Emitoyen between natural: 4 g + 20 mi ether / natural drying azure and turquoise blue]
mineral: t96 / production process: intense royal blue 235 2 g + Na2CO3 2 g / 0 # 1037 C + 1 h at 1037 C
mineral: # 67 / production process: intense royal blue 236 finely ground and heated powder of 0 # 593 C:
.50 g + HNO3 15 ml / soaking: 2 days / drying
slow on a hot plate: .1 g + 50 cc
transparent polyester resin + 1% cata
lyser i manual grinding I molding / depositing in
a tightly closed and deposited container
in an oven for plastics at 37 C juice
that hardening
mineral: # 67 / production process: royal blue very 237 stone covered with HNOs 20 ml / soaking: l powerful sem. I irradiated with radiation γ at 11.4 Mrad I
drying on sand bath i color of the liquid
mineral: # 95 / production process: intense royal blue 238 1 g + Na2C03 2.50 g / 982 C / 1 h and dark
mineral: # 49 / production process: royal blue acute 239 stone irradiated with electronic radiation at
(light purple tone) 319,882 rad, then neutron radiation
mineral: # 67 i production process: royal blue very 240 finely ground and heated powder of 648 OC: intense (green tone .50 g + H2SO4 15 mi I soaking: 2 d / emerald drying, slow on hotplate:. 50 g + 50 cc
transparent polyester resin + 17. cata
# lyseur / manual grinding / deposit in a tale
I nant closed a lid and deposited in a
oven for plastics at 37 C up to
curing
irradiated with radiation # to: royal blue (tone 241 5.7 Mrad emerald green) + dark and accentuates that very intense royal blue (emerald green tone) # royal blue much 242 17.1 Mrad darker (emerald green tone)
mineral: 17 t production process: a) emerald blue 243 2 g + HNO3 20 ml + HCl 5 ml I soaking: 6 days / medium, very strong separation of liquid and solid / drying b) natural phthalo green / color of a) liquid b) solid 'medium / blue intense green
Minerals: # 81 + # 98 f Production Process: Emerald Blue 244 1 g # 81 + Na2C () 3 2 g / 0 # 926 C / Cooling Off / Adding Lg * 98 I 0 # 926 C mineral: # 64 / production process: very emerald blue 245 1 g + 6.50 g glass powder (powerful spruce pine batch) / manual grinding / deposit on a plate
I ceramic biscuit I heating in a
oven of 0 # 1000 C in normal atmosphere i
| slow cooling in the oven
#
a little darker 246 irradiated with radiation at 7.41 Mrad
mineral: 17 / production process: a) emerald blue 247 2 g + HNO3 25 ml i soaking: 6 ji bright and dark separation of liquid and solid i natural drying I b) light azure blue color of a) liquid b ) of material / green discomfort [middle of solid liquid c) between apple green and mint green] c) moss green
Minerals: 9 + # 98 I production process: phthalo blue 248 lg # 9 + Na2CO3 2 g + lg # 98/0 # 926 C
Minerals: # 107 + # 98 / Production Process: Phthalo Blue 249 1 g # 107 + Na2CO3 3 g + 1 g # 98/0 # 871 C
Minerals: # 109 + # 98 / Production Process: Phthalo Blue 250 .50 g # 109 + Na2CO3 .50 g + .50 g # 98 /
926 C. / 1 h
Minerals: # 97 + # 98 / Production Process: Phthalo Blue 251 1 g # 97 + Na2CO3 2 g + 1 g # 98/871 C Bright & Dark / 1 hr
mineral: 10 production process:
2 g + Na2CO3 2 g: blue gray 252 0 # 871 C + 1 h at 871 ° C
# 253 0 # 1037 C + 1 h to 1037 C
mineral: # 17 / production process: a) blue gray 254 12 g + H3PO4 40 ml i soaking: 3 hi separab) blue gray 1st liquid and solid I add c) gray H3P04 40 ml to the same solid i soaking: 1 week

/ separation of the 2nd liquid and the solid /
hot plate drying (hum.) / color
a) 1st liquid b) 2nd liquid c) solid
mineral: * 34 / production process: blue gray 255 100 g + HCl 100 ml / soaking: 5 m. / drying
on hot plate / 0 # 260 C: .50 g +
NH4OH 5 ml / natural drying
mineral: 441 I production process: blue gray 256 lg + 1 cc white synthetic enamel paint
transparent for auto / manual grinding / ap
plication on a piece of body sheet
measuring 1 "x 1" / radiation irradiated # to
3.77 Mrad
mineral: # 74 / production method: blue gray 257 2 g + Na2CO3 2 g / 0 # 982 C + 1 h at 982 C
mineral: # 96 / production process: blue gray 258 2 g + Na2CO3 2 g / 0 # 926 C + lh at 926 oC
mineral: * 57 / production process: dark gray blue 259 2 g + Na2CO3 2 g / 0 # 593 C + 1 h at 593 C
irradiated with radiation # at 64.7 Mrad
mineral: t67 / production process: blue gray (tone 260 2 g + Na2CO3 2 g / 0 # 593 C + 1 h at 593 C green) dark and / irradiated with radiation # at 423.88 Mrad intense
mineral: 3! 4 / production process: turquoise blue 261 2 g + Na2CO3 2 gi 0 # 982 OC + lh at 982 oC very clear / irradiated with electronic radiation at
302,831 rad
mineral: # 34 / production process: a) turquoise blue 262 100 g + HNO3 100 ml i soaking: 5 m. / very light drying b) natural green: 2 g + H3P04 20 ml / soaking: 3 days / very, very light drying on hotplate (hum.) / color
a) solid b) liquid
mineral: # 34 i production process: turquoise 263 100 g + HNO3 100 ml i soaking: 5 m. / very light natural drying / irradiated with electronic radiation
at 302,831 rad
mineral: # 34 / production process: turquoise + 264 100 g + HNO3 100 ml / soaking: 5 m. / clear drying than natural blue: .50 g + NH4OH 5 ml / natural clear turquoise drying
mineral: # 54 I production process: turquoise blue 265 1g + K2CO3 2g / 0 # 815 C clear
mineral: # 54 I production process: turquoise 266 2% is mixed with glass pate and the clear everything is fused at 1315 C
mineral: # 34 / production process: turquoise + 267 100 g + HNO3 100 ml / soaking: 5 ri. i dry dark than natural blue / 0 # 176 C light turquoise
mineral: # 34 / production process:
100 g + NHO3 100 ml / soaking: 5 m. / drying
natural i radiated to radiation # to: turquoise blue + 268 64.7 Dark Mrad than light turquoise blue 4 turquoise blue 269 424.7 Mrad + blue, intense and dark
mineral: # 34 / production process: turquoise 270 100 g + HCl 100 ml / soaking: 5 m. drying lighter than hot plate I 0 # 204 oC: .50 g + turquoise blue $ NH4OH 5 ml / irradiated with electron beam
than at 302,831 rad
mineral: # 34 / production process: turquoise 271 100 g + HCl 100 ml / soaking: 5 m. / drying lighter than the hotplate / 0 # 204 OC: .50 9 + turquoise blue NH4OH 5 ml / radiation irradiated # to
63.88 Mrad
mineral: # 34 / production process:
100 g + HCl 100 ml / soaking: 5 m. / drying
on hot plate: blue (light tone 272 .50 9 + NH4OH 5 ml / natural turquoise drying) blue (light tone 273 0t 176 C: .50 g + NH * OH 5 ml / natural turquoise drying) # turquoise blue 274 0 # 204 C: 50 g + NH 4 OH 5 ml / natural drying.
(accented green tone) # turquoise blue 275 0 # 218 C: .50 g + NH4OH 5 ml / natural drying
(your green accented + green tone)
mineral: # 109 / production process: turquoise blue 276 .50 g + Na2CO3.50 g / 871 C / 1 hr
mineral: # 34 I production process: a) turquoise blue 277 100 g + HCl 100 ml J soaking: 5 m. X drying b) light green on hot plate: 2 g + H3PO4 20 ml
soaking: 3 days / hot plate drying
(hum.) / color of a) solid b) liquid
mineral: # 22 i production process: a) turquoise 278 0 # 1037 C: .60 g + H3PO4 200 ml / soaking: medium b) white 4 years / drying on hot plate (hum.) /
color of a) liquid b) solid
mineral: # 64
mineral: # 92 / production process:
2 g + Na2CO3 2 g: light green blue 287 0 # 871 C + 1 h at 871 C
# 288 0 # 1037 C + 1 h to 1037 C
mineral: # 22 / production process: a) blue green 289 0 # 1037 C: 1 g + HNO3 80 ml / soaking: 2 wk. b) dark green / separation of liquid and solid / drying c) very light green natural part of the liquid; drying at
desiccator another part of the liquid and
solid / color of a) dried antu
(b) dried liquid in the desiccator
c) solid
mineral: # 11 / production process: blue green 290 .30 g + Na2CO3 .50 g / 926 C / 1 hr
mineral: # 64 / production process: blue green a little + 291 2g + HCl 25ml / natural drying / irradiated to dark as blue radiation # to 64.7 Mrad light green
mineral: 28 / production process: blue green 292 2 g + H2SO4 20 ml / soaking: 3 d / drying
on hot plate
mineral: # 28 / production method: green blues and 293 1 g + NH4OH 1 ml / natural drying various green 294 1 g + NH4OH 5 ml / natural drying
# 295 1 g + NH4OH 10 ml / natural drying
# 296 1 g + NH4OH 15 ml / natural drying
# 297 1 g + NH4OH 20 ml / natural drying
# 298 1 g + NH4OH 25 ml / natural drying
mineral: # 34 / production process: blue green 299 100 g + HCl 100 ml / soaking: 5 m. / drying
natural: 4 g + NH4OH 20 ml / natural drying
mineral: # 96 / production method: blue green 300 2 g + Na2CO3 2 g / 0 # 982 C + 1 h at 982 C
mineral: # 109 / production method: blue green 301 1 g + Na2CO3 1.50 g / 871 C / 1 h
mineral: # 4 / production process: intense green blue 302 1 g + Na2CO3 1 g / 871 C / 1 hr
mineral: # 10 / production method: intense green blue 303 .76 g + Na2CO3 1.26 g / 926 C / 1 hr
mineral: # 61 / production process:
2 g + Na2CO3 2 g: intense green blue 304 0 # 982 C + 1 h at 982 C # still + intense 305 0 # 1037 C + 1 h at 1037 C
mineral: # 64 / production process: intense green blue 306 100 g + HCl 100 ml / soaking: 5 m. / drying
on a hot plate: 4 g + NH4OH 20 ml /
natural drying
mineral: # 74 / production process: intense green blue 307 2g + Na2CO3 2 g / 0 # 926 C + 1 h at 926 C
mineral: # 34 I production process: brighter green blue 308 stone covered with 1000 ml acetic acid than green blue / natural drying / intense crystal picking on stone: 5 g + NH4OH 25 ml / drying
natural I irradiated with radiation @ at 64.7 Mrad
mineral: # 64 / production process: blue green plus 309 2 g + H2SO4 20 ml / natural drying / irradiated bright than blue to radiation # to 64.7 Mrad intense green
mineral: # 67 i production process:
finely ground and heated: very green blue 310 0t482 C: .50 g + HCl 15 ml / soaking: 2 d / intense slow drying on hot plate very green blue 311 0 # 537 C: .50 g + HCl 15 ml / soaking: 2 d / intense (plus slow drying on blue hot plate) blue green very 312 0 # @ 537 C: .50 g + H2SO4 15 ml / soaking: 2 days intense / slow drying on hot plate
mineral: # 67 / production method: deep blue 313 3 g finely ground + HNO3 30 ml / soaking:
(3 days green reflection / hot plate drying: 1.50 g + emerald) 50 cc transparent polyester resin + 1%
catalyst I manual grinding f molding / die
in a closed container, deposited in a
oven for plastics at 37 C up to
curing
mineral: * 109 / production process: very green blue 314 1 g + Na2CO3 2 g / 871 C / 1 h intense
mineral: # 17 / production process: a) very green blue 315 12 g + HNO3 40 ml J soaking: 3 h / intense and saturated separation of the 1st liquid and the solid I rest of the very strong blue liquid b1 for 5 days drying on a sand bath of the first and bright c) liquid green / immediately after the separation of the medium turquoise liquid and the solid, addition to the same solid d) light gray green of HNO3 40 mi / soaking: 1 j / separation of the
(your orange) 2nd liquid and the same solid / rest of the 2nd li
quid for 5 days / drying the 2nd liquid on
sand bath / immediately after the separation
2nd liquid and solid, adding HNOz
40 ml at the same solid / soaking: 5 days / separates
3rd liquid and the same solid / drying
on sand bath / color of a) 1st liquid
b) 2nd liquid c) 3rd liquid d) solid
mineral: # 4 I production process: dark green blue 316 2 g + Na2CO3 2 g / 0 # 982 C + 1 h at 982 C
/ irradiated with radiation # at 64.7 Marad
mineral: # 95 / production process: dark green blue 317 1 g + Na2CO3 2.50 g / 1037 C / 30 min
mineral: 85 I production process:
1 g + Na2COs 1 g: dark green blue 318 871 C / 1 h and bright 319 926 C / 1 h
mineral: i34 t production process: peacock blue 320 100 g + HCl 100 ml J soaking: 5 m. i drying
on hot plate / 0 # 232 C .50 g +
NH4OH 5 ml / natural drying
mineral: * 99 I production process: peacock blue 321 2 g + Na2CO3 2 g / 0 # 926 C + 1 h at 926 C /
irradiated with radiation # at 64.7 Mrad
mineral: # 67 I production process: peacock blue plus 322 finely ground and heated from 0 # 537 C: .50 g intense and dark + HCl 15 ml I soaking: 2 i slow drying on
hotplate: .15 g + 6 cc polymer to
concrete + 0.18 cc catalyst + 1.50 thousandth
cobalt 6% + 2 g Portland cement i
manual grinding / molding / hardening / ir
Radiated to radiation # at 18.85 Mrad
mineral: # 95 I production process: a) peacock blue 323 0 # 1037 C: .30 g + HCl 50 ml I soaking: 2 very intense week. I separation of liquid and solid I b) olive green drying on heating plate / color of intense a) liquid b) solid
mineral: 42, process of production:
5 g stones + 13.74 g Portland cement +
6.50 cc water / mixing / molding I harden
Peacock blue 324 0 # 315 CI cooling I irradiated with small radius (light tone @ at 18.85 Mrad I color of gray stones) peacock blue 325 0 # 704 C / cooling / irradiated with intense ray (tone # at 18.85 Mrad / color gray stones)
mineral: # 6 / production process: blue green plus 326 radiation irradiated powder # at 550.22 Mrad
Forced that the pale blue green
mineral: # 67 / production method: very fine blue green 327 finely crushed and heated from 0 # 482 C: .50 g clear + HCl 15 ml / soaking 2 i slow drying over
hotplate: .1g + 50cc resin from
transparent polyester + 1% catalyst i
manual grinding / storage in a closed container
t hardening
mineral: 12, process of production:
2 g + Na2C0-3 2 g: light green (light 328 0 # 815 C + + 1 hr at 815 oC blue tone) 327 0 # 871 + 1 hr at 871 C # light blue green 330 0 # 926 C + 1 hr at 926 C
mineral: 1 / production process: green blue 331 2 g + Na2CO3 2 g / 0 # 1037 C + 1 h at 1037 C
mineral: 20 / production process: blue green 332 2 g + Na2CO3 2 g / 926 C / 1 h
mineral: # 74 / production process: blue green 333 2 g + Na2CO3 2 g J 0 # 1037 C + 1 h at 1037 C
mineral: # 8 / production process:
2 g + K2CO3 1 g: green blue 334 0 # 815 C green blue + intense 335 0 # 926 C + even more intense 336 0 # 982 C
mineral: 34 / production process: light blue green 337 stone covered with 1000 ml of acetic acid and bright as the J natural drying J levy of 5 g of green well intense crystals on the stone + NH4DH 25 ml / drying
natural / irradiated with electronic radiation
at 302,831 rad
mineral: 17 / production method: intense blue green 338 1 g + Na2CO3 1 g / 926 C / 1 h
mineral: # 67 / production process: dark blue green 339 finely ground and heated from 0 # 482 C: .50 g
+ HCl 15 ml / soaking: 2 i drying on pla
as heating: .15 g + 6 cc concrete polymer
+ 0.18 cc catalyst + 1.50 thousandth of g
6% cobalt + 2 g of Portland cement / grinding
manual / molding / curing / irradiated at
radiation at 18.85 Mrad
mineral: # 34 / production process: blue green plus 340 100 c + HCl 100 ml i soaking: 5 ml I dark drying as green on hot plate Day 204 C: .50 g pronounced blue NH4OH 5 ml / natural drying
mineral: # 95 / production process: dark green (reflection 341 1 g + 6.50 g glass powder (blue spruce pine) batch) J manual grinding / deposit on a plate
of ceramic biscuit / heating in a
oven of 0 # 1000 C in normal atmosphere i
slow cooling in the oven / irradiated
radiation at 7.41 Mrad
mineral: # 76 f production process: lighter blue green 342 0.14061 g indigo irradiated with X-ray as blue green 2.26 Mrad + 0.14061 g dried pork blood very dark and irradiated with radiation # at 2.26 Mrad +
0.14061 g zirconium oxide / grinding
mineral: 17 production process: a) blue green / 343 2 g + HCl 10 ml + HNO3 15 ml / soaking: 6 d / clear apple green separation of liquid and solid J drying and bright b) natural green I color of the a) liquid b) light solid / green acclimated
mineral: 107 w production process: blue green p @ 344 2 g + Na2CO3 3 g / 0 # 815 C + 30 min (gray tone) 815 C
mineral: * 67 f production process: blue green (345 2 g tones + Na2CO3 2 g / 0 # 482 C + 1 h at 482 C / gray) irradiated with radiation # at 423.88 Mrad
mineral: * 5f production process:
50 g + HCl 200 ml or asbestos covered with HCl
Soaking: 1 week i drying on heating plate
wax: light turquoise green 346 lg + Na2C03 4 g 1 01815 C light turquoise green 347 4 g + Na2CO3 3 cf 0 # 982 C turquoise green + bright 348 4 9 + Na2CO3 3 g; 0 # 1037 C light turquoise green 34 3 g + Na2CO3 4 g / 0 # 871 C medium turquoise green 350 3 g + Na2CO3 4 g / 0 # 926 OC turquoise green acute 351 3 g + Na2CO3 4 g / 0t982 C light turquoise green 352 2 g + Na2COz 3 g! 0 # 926 C acute turquoise green 353 2g + Na2CO3 3g / 0 # 982 C turquoise green + bright 354 2g + Na2C05 3 gf 0 # 1037 C
mineral: # 34 / production process: a) turquoise green 355 50 g + H3PO4 100 ml / soaking: 3 wk. / clear b) green drying on heating plate (hum.) / very light turquoise color of a) liquid b) sollde
mineral: # 54 / production process: light turquoise green 1 g + K2CO3 3 g / 0 # 815 C
mineral: * 67 / production process: light turquoise green 357 finely ground and heated from 0 to 537 C:
.50 g + H2SO4 15 ml / soaking: 2 days drying
slow on a hot plate: .25 g + 6 cc
concrete polymer + 0.18 cc catalyst + 1.50
thousandth of a g of cobalt 6% + 2 g cement
Portland f manual grinding / hardened molding
irradiation with irradiation # at 18.85 Mrad
mineral: 34f production process:
100 g + HCl 100 ml soaking: 5 m. drying
natural:
light turquoise green 358 .50 g + NH4OH 5 ml / natural drying
turquoise green a 359 0 # 176 C: .50 g + NH4OH 5 ml / natural drying
little green
still a little + green 360 0 # 204 C: .50 g + NH4OH 5 ml / natural drying #
still a little + green 361 0 # 232 C: .50 g + NH4OH 5 ml / natural drying
mineral: 17, production process:
a) turquoise green 362 2 g + HCl 25 ml / soaking: 6 days / separation
clear b) yellow green of liquid and solid / natural drying /
clear color of a) liquid b) solid
mineral: 28 / production method: light turquoise green 363 2 g + HCl 25 ml / natural drying / irradiated with
and quite intense radiation # to 424.7 Mrad
mineral: 28 / production process:
turquoise green + 364 irradiated granules with radiation # at 364 dark Mrad (green tone
emphasized)
mineral: # 9 / production process:
turquoise green 365 2 g + Na2CO3 2 g / 0 # 871 C + 1 hr at 871 ° C
mineral: # 107 / production process: turquoise green 366 .25 g + Na2CO3 1. 25 g / 926 C / 1 hr
mineral: # 34 / production process: turquoise green 367 100 g + HNO3 100 ml / soaking: 5 m. / drying
natural / 0 # 191 C
mineral: # 30 / production process: a) turquoise green 368 4 g + HNO3 50 ml / soaking: 4 wk. / separab) light green (liquid and solid / drying on blue ger ton) sand bath / color of a) liquid
b) solid
mineral: # 64 / production process: turquoise green 369 0 # 260 C: .50 g + NH4 OH 5 ml / natural drying
mineral: # 64 / production process: turquoise green 370 1 g + NH4OH 25 ml / pronounced natural drying
mineral: 17 / production process: turquoise green + 371 2 g + HNO3 20 ml + HCl 5 ml / soaking: 6 d / pale green separation of liquid and solid / natural medium turquoise drying / radiation irradiated # 65.65 Mrad
mineral: # 34 / production process: turquoise green 372 100 g + HCl 100 ml / soaking: 5 m. / drying slightly lighter than on heating plate / irradiated with radiation turquoise green # at 424.7 Mrad medium # green turquoise 373 100 g + HCl 100 ml / soaking: 5 m. / drying less pronounced on hotplate / 0 # 204 C than medium turquoise green
mineral: 5, production process:
50 g + HCl 200 ml or asbestos covered with
HCl / soaking: 1 week / drying on plate
heating: bright turquoise green 374 2g + Na2CO3 4g / 0 # 926 C @ turquoise green a 375 2g + Na2CO3 4g / 0 # 982 C little + dark green turquoise 376 4g + Na2CO3 4g / Ot 871C accented @
@ still + accented 377 4g + Na2CO3 4g / 0 # 926 C @ still + accented 378 4g + Na2CO3 4g / 0 # 982 C # turquoise green acute 379 4g + Na2CO3 4g 0 # 1037 C
mineral: 17 production process: a) turquoise green 380 1 g + HNOs 20 ml I soaking: 6 d / pronounced separation b) green liquid and solid I natural drying / pale apple color of a) liquid b) solid
mineral: # 95 / production process: a) turquoise green 381 3 g + HCl 80 ml J soaking: 4 years / very pronounced iridescent drying on heating plate / color of a) liquid b) gray b) solid
mineral: * 9 / production process: pale turquoise green 382 2 g + Na2CO3 2 g / 0 # 926 C + 1 h at 926 C / olive green
mineral: 5, production process:
50 g + HCl 200 ml or asbestos covered with HCl
I soaking: 1 week / drying on heating plate
fante: turquoise green 1 383 3 g + Na2CO3 2 g 1 0 # 982 oC emerald green @ turquoise green / 384 3 g + Na2CO3 2 g / 0 # 1037 C apple green @ turquoise green / 385 3 g + Na2CO3 2 g / 0 # 1093 C turquoise green apple green / 386 4g + Na2C03 3g / 0 # 1093 C pastel blue medium gray
mineral: * 17 X production process: a) turquoise green 387 1 g + HCl 10 ml I soaking: ó j / dark separation I olive green of liquid and solid 1 natural drying i dark b) orange color of a) liquid b ) green solid a) turquoise green 388 lg + HCI 20 minutes / soaking: 6 days I dark and bright separation J liquid and solid / natural drying / dark olive green color a) liquid b) solid b) beige ia) green turquoise 389 1 g + HCl 30 ml / soaking: 6 i dark separation I green liquid and solid / natural drying / dark olive color a) liquid b) solid b) beige
mineral: # 64 I production process: turquoise green 390 0 # 315 C: .50 g + NH4OH 5 ml / natural drying (brown tone)
mineral: t5 / production process:
50 g + HICI 200 ml or asbestos covered with HCl
I soaking: 1 week J drying on hotplate: turquoise green 391 1 g + Na2CO3 3 g / Ot 871 C very, very pale (gray tone) @ turquoise green 392 1 g + Na2CO3 3 g / 0 # 926 C light (gray tone) @ turquoise green a 393 1 g + Na2CO3 3 g / 0 # 982 C little + acute (gray tone) @ turquoise green 394 1 g + Na2CO3 4 g / 0 # 871 C light (light gray tone) turquoise green 395 1 g + Na2CO3 4 g / 0 # 926 C a little + dark 396 lg + Na2CO3 4 g / 0 # 982 C
mineral: # 34 / production process: turquoise green 397 100 g + HCl 100 ml / soaking: 5 m. / drying (light gray tone) natural 1 0 # 315 C: .50 g + NH4OH 5 mi I
natural drying
mineral: t34 i production process: turquoise green 398 100 g + HCl 100 ml / soaking: 5 m. / drying (light gray tone) on hotplate 1 0 # 218 C
mineral: # 64 / production process:
1 g + NH4OH 2 ml / maturel / irradiated drying
at radiation: green turquoise 399 electronic at 302,831 rad foam + clear turquoise green clear foam I 4 green turquoise 400 @ to 64.7 mrad foam + green and accented as turquoise green clear foam
mineral: # 64 / production process: turquoise green 401 1 g + NH4OH 1 ml / natural drying foam 402 5 g + NH4OH 25 ml / natural drying
mineral: 5 / production process: light green 403 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on heating plate: .50 g + Na2CO3 .50 g / 0 # 1037 C / ir-
Radiation at radiation @ 65.65 Mrad
mineral: # 6 / production process: light green 404 irradiated stone @ radiation at 615.924
mineral: # 109 / production process: light green 405 2 g + Na2CO3 2 g / 0 # 871 C + 1 h at 871 ° C /
irradiated with radiation @ at 190.22 Mrad
mineral: # 5 / production process: a) very light green 406 15 g + H3PO4 100 ml / soaking: 3 wk. / b) medium gray separation of liquid and solid / drying
on hot plate (hum.) / color of
a) liquid b) solid
Minerals: # 18 + # 26 / Production Process:
1.50 g # 18 + .50 g # 26 / crushed and bumped
with water until paste consistency: very light green 407 760 C / 1 h
# 408 815 C / 1 h
mineral: 17 / production process: green a little + clear 409 2g + HNO3 15ml + HCl 10ml / soaking: 6 @ / only light green separation of liquid and solid / drying
natural / radiation irradiated @ 65.65
mrad
mineral: 28 / production method: light green 410 1 g + NH4OH 25 ml / natural drying: .2 g + 50
cc transparent polyester resin + 1%
Catalyst / shredding nanuel / deposit in a
closed container and placed in an oven for
plastics at 37 C until hardening
mineral: 5, production process:
.50 g + Na2Co3 .50 g: light green 411 0 # 982 C
# 412 0 # 1037 C
Minenal: 24 / production process: a) light green 413 2 g + H3PO4 20 ml / soaking: 3 d / drying b) gray on hot plate (hum.) / color of
a) liquid b) solid
mineral: # 25 / production method: light green 414 2 g + Na2CO3 2 g / 0 # 815 C + 30 min at 815 C
mineral: # 34 / production process: a) light green 415 100 g + HCl 100 ml / soaking: 5 n. / drying b) light gray natural: 2 g + H3P04 20 ml / soaking: 3 d /
hot plate drying (hum.) / color
a) liquid b) solid
Mineral number: 53 + 39 / + 93 / production method: light green 416 # 53 is heated from Ot 760 C: lg + 1 g # 39:
.50 g + Na2CO3 .50 g + .50 g, 93/926 C /
1 h
mineral: # 61 / production process: green more pronounced 417 2 g + Na2CO3 2 g / 0 # 815 C + 1 hr at 815 C as light green
mineral: # 82 / production process: a) light green 418 4 g + H3PO4 20 ml / soaking: 3 wk. i drying b) gray on hot plate (hum.) / color of
a) liquid b) solid
mineral: 5, production process:
3 g + Na2CO3 4 g: intense light green 419 0 # 982 C
# 420 0 # 1037 C
mineral: # 109 i production process: green + bright as 421 2g + Na2CO3 2g / 0 # 815c + 1h to 815c light green accented
mineral: 28 / production process: green a little bright 422 5 g + NH4OH 25 ml / natural drying / irradiated as light green to radiation @ 64.7 Mrad
mineral: t28 i production process: dark green + 423 1 g + NH4OH 4 ml natural drying: .20 g + light green 50 cc transparent polyester resin + 17.
catalyst / manual grinding I molding i
hardening / irradiated with electro radiation
at 155,082 rad
mineral: 5, production process: green 424 2 g + Na2CO3 2 g / 1037 C / 1 h
mineral: # 67 / production method: streaks: green / brown 425 0t704 C + 4 h to 704 OC: l 9 + 6.50 g dark orange / ca-glass powder (spruce pine batch) / 0 # 1000 C orange ram medium I slow cooling in the oven
mineral: # 6 / production process: green 426 4 g + HNO3 50 ml / soaking: 4 wk. / drying
on heating plate / irradiated with radiation
@ to 190.22 Mrad
mineral: # 50 / production process:
27.4 g Portland cement + 13 cc water i
manual grinding / molding / immediate deposition of
lg # 50 on the piece of wet cement f hard
addition of 5 g # 50 on the surface of the
dried cement: green / yellow / brown 427 0 # 1037 C dark / orange 28 0 # 1065 C
mineral: # 50 / production process: green / orange 429 2 g + Na2CO3 2 g / 760 C / 1 hr
Minerals: 50 + 53 I Production Process: Green I brown 430 lg # 53 integrated to the mass of 27.4 g cement
Portland + 13 cc water / manual / soft grinding
lage i hardening 1 added on the cement sé
3 g # 50/0 # 926 C
Minerals: 50 + 100 J production process:
2 g # 50 + Na2CO3 2 g I deposit on a stone
# 100: green 431,926 C / 1 h
# 432 982 C / 1 h green / brown 433 1037 C / 1 h
mineral: # 64 / production method: green 434 5 g + NH4OH 25 ml / natural drying J irradiated
at radiation @ at 424.7 Mrad
mineral: 5, production process:
0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
green HCl / soaking: 1 week / drying on
hot plate: .50 g + Na2CO3 50 g: green 435 0 # 815 OC
436 0 # 871 C
i 437 Ot 926 C
# 438 0 # 1037 C
mineral: # 9 / production process:
2 g + Na2CO3 2 g: green 440 0 # 982 C + 1 h at 982 C
# 441 0 # 1037 C + 1 h to 1037 C
mineral: 20 / production process: green 442 2 g + Na2CO3 3 g / 926 C / 1 h
mineral: # 25 / production method: green 443 2 g + Na2CO3 2 g / 0 # 815 C + 1 hr at 815 ° C
mineral: # 34 / production process: a) green b) green 444 100 g + HNO3 100 ml / soaking: 5 m. ia) cold green 447 0t 1037 C: 1 g + H3PO4 20 ml i soaking: 4 years b) gray i drying on heating plate (hum.) / neck
their a) liquid b) solid
mineral: 102 production process: green 448 1 g + HCl 100 ml / soaking: 2 wk. / drying
on hot plate
mineral: # 78 i production process: a) green b) gray 449 0 # 1037 C: .50 g + H2PO4 80 ml / soaking:
2 weeks / drying on a hot plate (hum.)
/ color of a) liquid b) solid
Mineral: Production method: medium green 450 g + H2SO4 200 ml; soaking: 4 weeks i dried
# ge on hot plate a little + green 451 irradiated with radiation y to 190.22 Mrad
mineral: 1 / production method: intense green 452 2 g + Na2CO3 2 g / 0 # 982 C + 1 h at 982 C
mineral: 1 / production method: bright green and full-bodied 453 stone covered with HCl 20 ml / soaking: 2
wk. irradiated with gamma radiation; at 5.7 Mrad /
drying on a sand bath
Minerals: 107 + 98 Production Process: Green Accented 454 lg # 107 + Na2CO3 1.50 g J 871 C i 8 h:
.50 g + .50 g # 98 / radiation irradiated γ
at 63.984 Mrad
mineral: t34 I production process: very intense green 455 iOO g + HNO3 100 ml / soaking: 5 m. I drying
natural: .1g + 50cc polyester resin
transparent + 1% catalyst J grinding my
nuel / deposit in a closed container of a
lid and placed in an oven for
plastics at 37 C until hardening
mineral: # 27 I production process: very green 456 0 # 1037 C: .50 g + H3PO4 50 ml / soaking: 2 powerful sem. / hot plate drying (hum.)
mineral: 27 / production method: deep green 457 0 # 1037 C: 1 g + H2SO4 50 ml / soaking: 2
wk. / drying on a hot plate
mineral: * 95 I production process: a) very bright green 458 oq + HCl 80 ml f soaking: 2 wk. / separa- b) green kaki tion of liquid and solid / drying on
hot plate / color of a) liquid
b) solid
mineral: production method: dark green 459 2 g + Na2CO3 2 g / 0 982 C + 1 h at 982 ° C
radiation irradiated γ to 64.7 Mrad minerals: * 5 + T50 I production process:
dark green / brown 460 lg # 5 integral to the mass of 27.4 g cement
orange / gray iron Portland + 13 cc water i manual / soft grinding
/ yellow / orange / hardening / addition to the cement se
3 g # 50/0 # 926 C
mineral:

* * 50 i production process:
4 g 50 deposited on a piece of steel
stainless measuring 1 x 1 ":
dark green I brown 461 760. PC / 10 min / withdrawal 'immediate #
green a little light + 462 760 C / 13 min / immediate withdrawal #
green again + clear 463 760 C / 16 min / immediate withdrawal #
green again + clear 464 760 C f 19 min / immediate withdrawal
mineral: # 50 / production process:
areas: dark green 465 1 g + 6.50 g glass powder (spruce pine
/ brown caramel batch) I manual grinding / deposit on a pla
dark than ceramic biscuit I heating in
an oven of 0 # 1000 C in a normal atmosphere /
slow cooling in the oven
mineral: # 61 I production process:
dark green 466 2 g + Na2CO3 2 g / Ot 1037 C + 1h at 1037 C
irradiated with radiation # at 64.7 Mrad
mineral: 26, process of production:
dark green 467 1 g + 6.50 g glass powder (spruce pine
batch) / manual grinding / deposit on a plate
of ceramic biscuit / heating in a
oven of 0 # 1000 C in normal atmosphere i
slow cooling in the oven irradiated J
radiation γ at 9.88 Mrad
mineral: # 5 / production process:
light green / beige 468 50 g + Na2CO3 .50 g / 0 # 926 C
mineral: 5 production process:
very mint green 469 250 g + HCl 1650 ml in a 2000 ml beaker
clear and localized or asbestos covered with HCl in a tale
(light gray tone) nant in height / soaking: l wk. drying
on heating plate (3-layer formation
of superimposed colors, including the deep one
color: apple green): 3 g + 27.4 g cement
Portland + 13 cc water / manual / soft grinding
aging / curing / 0 # 1065 C
mineral: # 6 I production process:
mint green plus 470 gamma irradiated powder at 424.7
pale as the green mrad
light mint
mineral: 1, process of production:
light mint green 471 3 g + H2SO4 50 ml / soaking time: 2 weeks / drying
on hot plate
mineral: 34 f Production method: light mint green 472 100 g + HCl 100 ml / soaking: 5 m. i drying
on hot plate / 0 # 218 C: .50 g +
NH4OH 5 ml J natural drying: .2 g + 50 cc
transparent polyester resin + 1% cata
lyser / manual grinding / deposit in a tale
closed with a lid / hardening
mineral: # 22 f production process: light mint green 473 0 # 1037 OC: 1 g + H2SO4 50 ml / soaking: 2
wk. i separation of liquid and solid f
drying on hotplate / irradiated at
radiation γ at 64.7 Mrad
mineral: # 24 / production method: clear green light 474 5 g + H2SO4 20 ml / soaking: 3 d / drying
on hot plate
mineral: # 22 / production process: a) mint green 475 4 g + H2SO4 100 ml f soaking: 2 wk. f sepaclair and intense ration of liquid and solid I drying on b) olive green hot plate / color of a) intense liquid b) solid
mineral: # 63 I production process: mint green plus 476 radiation irradiated powder at 360 Mrad saturated than light mint green
mineral: # 87 I production process: mint green 477 1% # 87 mixed with glass paste and + dark fused at 1315 C / irradiation mint green at gamma radiation; at 7.41 Mrad
mineral: t27 / production process: intense mint green 478 2 g + H3PO4 20 ml / soaking: 3 d / drying and dark on sand bath
mineral: # 6 / production method: intense mint green 479 250 g + HCl 1650 ml in a 2000 ml beaker
or asbestos covered with HCl in a container
in height / soaking: 1 wk. I drying on
hot plate (formation of 2 layers of
superimposed colors, including surface
is dark green [mint green genus]) / irradiated
radiation γ at 190.22 Mrad
mineral: # 11 f production process: intense mint green 480 2 g + Na2CO3 2 gf 0 # 871 C + 1 hr at 871 ° C
mineral: # 24 / production process: intense mint green 481 5 g + H2SO4 20 ml / soaking: 3 d / drying
on heating plate / irradiated with radiation
γ at 64.7 Mrad
mineral: * 6 f production process: a) dark green Egenre 482 250 g + HCl 1650 ml in a beaker of 2000 ml mint green3 b) green or asbestos covered with HCl in a dark container (light tone in height I soaking: l w / dry on yellow) hotplate (formation of 2 layers of
superimposed colors) / layer color
in a) surface b) depth
mineral: * 27 J production process: mint green (very 483 2g + H3PO4 20ml J soaking: 3d / drying light yellow tone) one on sand bath / irradiated with radiation # lightly + clear that the 64.7 Mrad green intense mint (yellow tone)
mineral: # 64 / production process: mint green (light 484 irradiated stone with y radiation at 360 Mrad yellow tone) + pale as pronounced mint green (yellow tone)
mineral: # 6 / production method: green [green genus 485 250 g - + HCi 1650 ml in a beaker of 2000 ml mint] a little + or asbestos covered with HCl in a dark container that green in height / soaking: 1 week I drying on accented mint heating plate (formation of 2 layers of brown iton) superimposed colors, including surface
is dark green [mint green genus]) / irradiated
radiation γ at 550.22 Mrad
mineral: # 34 i production process:
100 g + HL1 100 ml I soaking: 5 m. J drying
natural: green mint 486 0 # 204 C evolving 487 0 # 260 C slowly to 488 0 # 315 C the 489 0 # 374 C mint green 490 0 # 426 0 C dark (brown tone) 491 0 # 537 C
mineral: 28 I production process: mint green (light 492 2 g + 20 ml ether / natural drying gray tone)
mineral: # 25 i production method: mint green [type 493 2 g + Na2CO3 2 g / 0 # .815 C + 45 min at 815 C malachite green]
mineral: # 34 / production method: mint green [kind 494,100 g + HCl 100 ml J soaking; 5 m. / drying natural malachitel / 0 # 232 C / radiation irradiated
γ at 64.7 Mrad
Mineral: 27 / production method: mint green (kind 495 4 g + H2SO4 80 ml J soaking: 2 weeks / drying green malachitel on \ intense hotplate
mineral: # 6 / production method: dark coniferous green 496 4 g + HCl 100 ml J soaking: 2 wk. / drying
on heating plate i irradiated with radiation
at 550.22 Mrad
mineral: t17 / production process: phthalo green + 497 2 g + HCl 15 ml + HNO3 10 ml / soaking: 6 d / pale green separation of liquid and solid I clear natural phthalo drying / solid is irradiated to radiation
γ at 65.65 Mrad
mineral: 17 production process: a) phthalo green 498 1 g + HCl 50 ml dipping: 6 d / clear and high separation of liquid and solid I natural drying I b) very lime green, color of ) liquid b) very strong solid
mineral: 28 / production process: phthalo green 499 granules irradiated with radiation at 360 Mrad
mineral: # 95 / production method: phthalo green 500 3 g + HCl 80 ml / soaking: 2 wk. / separates
liquid and solid i drying on
hot plate i the solid is irradiated at
radiation at 64.7 Mrad
mineral: # 34 I production process: phthalo green + 501 100 g + HCl 100 ml dipping: 5 m. / intense drying as the natural / 0 # 232C / radiation irradiated γ phthalo green at 424.7 Mrad
mineral: 17 production process: phthalo green 502 2 g + HNOx 25 ml / soaking: 6 days / much + intense separation of liquid and solid / natural drying i the solid green is irradiated to gamma &radiation; at 65.65 phtalo
mineral: i24 / production process: a) phthalo green 503 stone irradiated with radiation # at 65 Mrad: b) bright apple green grinding J 1 g irradiated powder + HNO3 40 mi
/ natural drying J color of a) liquid
b) solid
mineral: # 24 J production process: a) phthalo green 504 1 g + HNOz 40 ml / natural drying J very intense color of a) liquid b) solid b) medium khaki green
mineral: # 34 I production process: phthalo green 505 stone covered with 1000 ml of acetic acid very intense and vivid / natural drying / crystal picking
on the stone: 1 g of crystals + NH4OH 4 ml /
natural drying: .20 g + 50 cc resin
transparent polyester + 1% catalyst /
manual grinding / molding / hardening / ir
radiation radiation γ at 5.7 Mrad
mineral: 17 production process: phthalo green 506 2 g + HN03 25 ml dipping: 6 d / very intense separation of liquid and solid i natural drying I
liquid is irradiated with radiation # at 425.65
mrad
mineral: * 22 i production process: phthalo green + 507 4 g + HNGs 100 ml /. tempering: 2 wk. separaintense and vif tion of the liquid and the solid I drying as the desiccant green of the 1st liquid / addition to the same sophtalo very intense lide of HND3 100 ml / soaking: 2 wk. / sep
ration of the 2nd liquid and the solid i drying at
2nd fluid desiccator / natural drying of the
solid / the 1st liquid is irradiated to the radius
γ at 424.7 Mrad
mineral: 17 production process: a) phthalo green 508 1 g + HNDO 50 ml / soaking: 6 d deep and dark separation of liquid and solid / natural drying I b) phthalo green color of a) liquid b) solid oyen
mineral: 17 production process: a) phthalo green 509 2 g + HCl 15 ml + HNO3 10 ml / soaking: 6 ml clear green for separation of liquid and solid! intense natural phthalo drying J color of a) solid b) liquid b) bright phthalo green
mineral: 17 / production process: phthalo green 510 2 g + HCl 15 mi + HNO3 10 mi J dipping: 6 d / (light green tone separation of liquid and solid / drying mint) many natural / liquid is radiation irradiated + intense γ at 65.65 Mrad
mineral: 17 production process: phthalo green 511 315 C / lh: lg + HCl 40 mi I soak: 14 (beige tone) + more separation of liquid and solid / dry and dark than natural chage the liquid is irradiated with pale phthalo green radiation γ at 65.65 Mrad (beige tone)
mineral: # 70 I production process: green adjoining between 512 1 g + Na2CO3 2 g / 0 # 982 oC phthalo green and olive green
mineral: 34 / production process: green lawn a little 513 stone covered with 1000 ml of acetic acid + clear as green / natural drying / crystal clear lawn removal on the stone: 5 g crystals + NH4OH 25 ml
I natural drying: tg + 1 cc printer ink
merie white opaque f manual grinding fl im
pressure on glossy / irradiated white paper
radiation γ at 22.8 Mard
minerals: # 18 + # 27 / production method: clear lawn green 514 1.50 g # 18 + .25 g # 27 J 1000 C i 2 h
# 515 1.50 g # 18 + .50 g # 27 l 1000 C / 2 hrs
# 516 1.50 g # 18 + .75 g # 27/1000 C / 2 hrs
# 517 1.50 g i18 + 1 g 27/1000 C / 2 h
# 518 1.50 g # 18 + .50 9 # 27/1010 C / 1 hr
# 519 1.50 g # 18 + .50 g # 27/0 # 1037 C
Minerals: 18 + # 26 / Production Method: Light green lawn 520 1 g # 18 + 1 g # 26 + 1 g MgO / 926 C / 1 hr
# 521 1 g # 18 + 1 g # 26 + 1 g MgO i 982 CJ 1 h
# 522 1.50 g # 18 + .50 g # 26 i 871 C l 1 hr
i 523 1.50 g # 18 + .i5 g # 26/887 C i 1 h
524 1.50 g # 18 + .25 g # 26/387 C / 1 h
# 525 1.50 g # 18 + .35 g # 26/898 C / 1 hr
526 1.50 g # 18 + .50 g t26 i 898 C / 1 h
# 527 1.50 g # 18 + .40 g t26 / 915 OC / 1 h + accented 528 1.50 g # 18 + .25 g # 26/898 C / 1 h still + accented 529 1.50 g # 18 +. 50 g # 26/915 OC I 1 h
Minerals: # 18 + # 27 / Production Method: Light green lawn 530 1.50 g # 27 + .25 g # 18/1000 C / 2 h + dark 531 1.50 g # 27 + .50 g # 18/1000 CI 2h still + dark 532 1.50 g # 27 + 1 g # 18 i 1000 C / 2 h
minerals: # 27 + # 29 / production method: light green lawn 533 1.50 g # 29 + .25 g 427/1000 cm 2 hr
# 534 1.50 g # 29 + .25 g # 27/832 C / 1 hr
# 535 1.50 g # 29 + .25 g # 27/915 C / 1 hr
mineral: 27 / production method: green lawn 536 .50 g # 27 + 1.50 g light pastel shell powder mold / 0 # 1037 C
mineral: # 30 I production method: light green lawn 537 4 g + H2SO4 50 ml / soaking: 4 wk. / drying
on hot plate
mineral: t64 i production method: light green lawn 538 1 g + NH4OH 25 ml / natural drying: .2 g + intense 50 cc transparent polyester resin + 1%
Catalyst / deposit in a closed container
a lid / hardening
minerals: # 4 + # 98 / production method: light green lawn 539 .50 g + .50 g / radiation irradiated (accented green tone) γ at 63.984 Mrad
minerals: # 26 +/- 29 / production method: green lawn light 540 1.50 g # 29 + .50 g # 26/871 oC '/ 1 h green lawn 541 1.50 g # 29 + .10 g & num 26/887 C / I h + accented 542 1.50 g * 29 + .15 g # 26/887 C / 1h still + accented 543 1.50 g # 29 + .10 g # 26/898 QC J ih
mineral: 27 / process of productin: green lawn + green, 544 1.50 g mold shell powder + .50 g bright and accentuated 27/0 # 1037 C / irradiated with radiation that green electronic lawn at 302,831 rad clear
mineral: # 3 / production method: green lawn 545 stone covered with HCl 20ml / soaking:
wk. / irradiated with radiation g at 5.7 Mrad /
drying on a sand bath
mineral: # 22 / production method: green lawn 546 4 g + NHO3 100 mi / soaking: 2 wk. i separated
first liquid and solid
desiccator of the liquid l addition to the same 50-
HNOx lide 100 ml / soaking time: 2 weeks / sep
2nd liquid and solid / drying
dessicator of the 2nd liquid i natural drying of
solid / the solid is irradiated with radiation
γ at 64.7 Mrad
Minerals: # 27 + # 29 / production method: green lawn 547 .50 g # 27 + 1.50 g # 29/1000 C / 1 hr
mineral: 27 / production process: green lawn 548 1g + 27.4g Portland cement + 13cc water
/ manual grinding / molding / hardening /
0 # 1037 C
mineral: 26 / production process: green lawn 549 1.50 g shell mold powder + .50 g
26/1037 C / 1 hr
mineral: # 109 / production method: green peel 550 .50 g + Na2CO3 2 g / 0 # 871 C + 1 hr at 871 ° C
minerals: # 26 + # 29 f production process: green lawn 551 1 g # 29 + .50 g # 26/926 C / 1 h + light & cold 552 1 g # 29 + .25 g & num 26/926 C / Ih still + 553 1 g # 29 + .10 g # 26/926 C / 1 h green perlouse 554 .50 g # 29 + 1.5G g # 26 i 926 oC iih of 555.50 g # 29 + 1 g * 26/926 C / 1 tones 556.50 g # 29 + 50 g # 26/926 OC / 1 hr varied # 557 .50 g # 29 +25 g # 26/926 C / 1 hr
# 558 .50 g # 29 + .10 g # 26/926 C / 1 h
mineral: # 107 / production process:
2 g + Na2CO3 2 g: green lawn 559 0 # 815 C + 1 hr at 815 C
| 560 0 # 926 C + 1 h to 926 C
1 561 0 # 1037 or + 1 hr at 1037 C of tones 1 562 1 g + Na2C05 .50 g J 871 CJ 1 h
# 563 1 g + Na2CO3 2 g / 871 0C / 1 h varied # 564 1 g + Na2CO3 2.50 g / 871 C / 1 h
Mineral: 87 / production process: green lawn 565 17. # 87 is mixed with glass paste from
(olive green reflection) type crystal and the whole is fused to
1315 C
minerals: #, 3 + * 26 / production process: green lawn + 566 3 g # 33 + 2 g # 26/926 C / ih clear than the average lawn green
mineral: 27 / production method: green pastel lawn 567 1.50 g mold shell powder + .50 g medium and cold 27/0 # 1037 C / radiation irradiated y
at 424.7 Mrad
mineral: # 5 / production method: medium green lawn 568 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on heating plate
fante: 3 g + Na2CO3 4 g / 0 # 1037 C
Minerals: # 26 + # 29 / production method: medium green peel 569 1.50 g # 29 + .25 g # 26/843 C / 1 hr
570 1.50 g # 29 + .25 g # 26/915 C / 1 hr
571 1.50 g # 29 + .25 g # 26/1010 C / 1 hr
Minerals: # 33 + # 68 / Production Method: Green Average Lawn 572 3 g # 33 + 2 g # 68/926 C / 1 hr
mineral: # 74 / production method: medium lawn green 573 2 g + Na2CO3 2 g / 0 # 1037 C + 1 h at 1037 C and intense / irradiated with gamma radiation at 423.88 Mrad
Minerals: 18 + # 26 / Production Method: Green Lawn Live 574 .50 g # 18 + 1.50 g # 26/926 C / 1 hr
Minerals: # 26 + # 29 / production method: green grass bright 575 1.50 g # 29 + .50 g # 26/926 C / 1 h green lawn + bright 576 1.50 g # 29 + .50 g # 26/982 C / 1 h green lawn bright 577 1 g # 29 + 1 g # 26 / crushed and moistened with water and bright water until paste consistency / 1093 C /
# 45 min
mineral: 26 / production method: green lawn bright 578 .74 g shell mold powder + 1 g # 26
/ 926 C / 1 h
mineral: 92 / production method: green grass bright 579 2 g + Na2CO3 2 g / 0 # 871 C + 45 min at 871 C
Minerals: num num + + + + + + + + 18 18 18 18 18 18 18 26 26::::::::::::::::::::::::::::::: &: &&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&&::::&:::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::::: / intense lawn 982 C / 3 h
mineral: 34 / production process: green lawn very 581 stone covered with 1000 ml of acetic acid intense / natural drying / crystal picking
on the stone: 2 g crystals + HCl 20 ml /
soaking: 2 weeks / radiation irradiated γ at
5.7 Mrad / drying on sand bath
mineral: # 11 / production process:
2 g + Na2CO3 2 g: green lawn 582 0 # 982 C + 1 h at 982 C powerful 583 0 # 1037 C + 1 h at 1037 C
mineral: # 107 / production process:
1 g + Na2CO3 1 g: green lawn 584 871 C / 1 h powerful # green lawn 585 871 C / 6 h powerful and dark
mineral: # 21 i production process:
2 g + Na2CO3 2 g: dark lawn green 586 0 # 815 C + 1 h to 815 C + accented and vivid 587 0 # 871 C + 1 h at 871 C again + 588 0 # 926 C + 1 h at 926 C
minerals: # 26 and # 29 / production method: dark lawn green 589 1 g + 1 g 1093 C / 45 min
Minerals: 18 &# 27 / production method: green lawn + clear 590 1.50 g # + 1.50 gi 1000 C / 1 h as dark green lawn
mineral: 5 / production method: dark lawn green 591 50g + HCl 200ml or asbestos fully
covered with HCl / soaking: 1
Minerals: # 18 + # 27 / Production Method: Very lawn green 601 1.50g + 1.50g / 1000c / 8h dark
Mineral: 95 / production process: very green lawn 602 3g + HCl 80ml / soaking: 2 wk. / separafonce Equasi black) liquid and solid / drying on
hot plate / the solid is irradiated at
radiation γ at 424.7 Mrad
Minerals: # 18 + # 26 / Production Process: Green Lawn Black 603 1.50 g # 18 + .25 g # 26/1287 C / 1 hr
# 604 1.50 g # 18 + .50 g # 26/1287 C / 1 h
mineral: # 9 / production method: light lawn green 605 2 g + Na2CO3 2 g / 0 # 815 C + 30 min at 815 C / orange
minerals: # 9 + # 98 i production process: dark lawn green 606 1 g + Na2CO3 2 g + 1 g / 0 # 871 C / black brown
Minerals: 18 + # 27 / Production Method: Light green lawn 607 .50 g # 27 + 1.50 # 18/1000 C / 2 h / irradiated
(slight blue tone) radiation γ at 64.7 Mrad
Minerals: # 18 + # 27 / Production Method: Green Lawn 608 1.50g + 1.50g / 1000c / 1h
(blue tone) 609 1 g # 27 + 1.50 g # 18/1000 C / 1 hr
# 610 .50 g # 27 + 1.50 g # 18/1000 C / 1 hr
Minerals: # 18 + # 26 / production method: green lawn 611 1g + 1g / 1093c / 45 min
(blue tone) 612 1 g + 1 g / crushed and moistened with water
# up to paste consistency / 1093 C / 45 min green lawn (very 613 1.50 g # 18 + .50 g & 26/926 C / 1 h light blue tone) green lawn (tone 614 1.50 g # 18 + .50 g # 26/1093 C / 1 h bluish still + dark # still + dark 615 1.50 g # 18 + .50 g # 26/1260 C / 1 h
Minerals: # 18 + # 27 / Production Method: Green Medium Lawn 616 .50 g # 27 + 1.50 g # 18/1000 C / 2 hr / irra
(light blue tone) with radiation γ at 424.7 Mrad
Minerals: # 19 + # 26 / Production Process: Intensive green lawn 617 .50 g # 19 + 1 g * 26/926 C i 1 h (light blue tone) green medium plouse 618 1 g # 19 + 1.50 g # 26/926 C / 1 hr
(blue tone) green lawn (tone 619 1g + 1g / 926c / 1h blue) a little + clear green lawn (tone 620 1g # 19 + .25g # 26 / 926c / 1h blue ) + clear 4 green lawn (tone 621 1.50 g # 19 + .50 g & 26/926 c / 1 h blue) + clear than the green medium lawn
mineral: 21 / production process: very lawn green 622 2g + Na2CO3 2g / 0 # 982C + 1h to 982C intense (blue tone)
minerals: # 18 + * 26 I production process: green lawn (tone 623 1.50 g * 18 + .50 g # 26/1037 QC i I h: .25 g blue3 a little + pale + HF 20 ml / soaking : 24 h / drying in a green lawn oven at 37 C dark (blue tone)
minerals: * 73 + # 7b / production process: green lawn (tone 624 0.14061 g # 73 irradiated with radiation y at 2.26 blue) + pale than Mrad + 0.14061 g indigo irradiated with rayonnele green lawn ment γ at 2.26 Mrad + 0.14061 g # 76 / dark grinding (blue tone)
mineral: i73 / production process: green lawn (tone 625 O.i4061 g # 73 irradiated with radiation y at 2.26 blue) a little + pale Mrad + 0.14061 g indigo irradiated with rayon the green lawn ment γ at 2.26 Mrad + Na2CO3 0.28122 g / dark (blue tone) grinding
mineral: # 73 J production process: dark green lawn 626 0.14061 g # 73 irradiated with X-radiation at 2.26 (blue tone) Mrad + 0.14061 g indigo irradiated with rayon
ment γ at 2.26 Mrad / grinding
Minerals: # 33 + # 26 f Production Process: Green Lawn (Tone 627 6 g # 33 + 2 g # 26/1037 C / 30 min blue) Dark
minerals: t18 + 26 / production method: green lawn (tone 628 1.50 g # 18 + .50 g # 26/1037 C / 1 h: .25 g blue) + intense + HCl 20 ml / soaking: 3 days drying on
hotplate
mineral: i5 / production process:
0 # 1037 OC: 50 g + HCl 200 ml or asbestos recou
green HCl / soaking: 1 week i drying on
hotplate: green lawn (tone 629 1g + 0.28122g indigo + 0.14961g black blue) a little + pale animal + 0.14061g MgO / grinding that green dark lawn (blue tone) green lawn (tone 630 1g + 0.28122g indigo + 0.14061 g black blue) a little + pale animal + Na2CO3 0.28122 g / grinding as dark green lawn (blue tone) # green lawn very 631 1g + 0.28122g indigo + 0.14061g dark black (animal blue tone / grinding very emphasized)
mineral: # 5 I production process: green lawn (tone 632 0 # 1037 OC: 50 g + HCl 200 ml or asbestos recoujaune) a little + pale green HCl / soaking: 1 wk. i drying on that green lawn hotplate: 1g + 0.14061g indigo + very intense (MgO tone 0.14061g / grinding yellow)
Minerals: # 20 + # 27 / production method: green lawn (light 633 1.50 g # 20 + .50 g # 27/1000 C / 2 h brown tone)
Minerals: 18 + P26 / production method: medium green lawn 634 1g + 1g + MgO 1g / 982c / 15h (light brown tone)
mineral: # 92 / production method: dark lawn green 635 2 g + Na2CO3 2 gi Ot 871 C + 1 h at 871 C and dark (brown tone) J irradiated with B radiation at 424.7 Mrad
Minerals: 18 + # 26 / production method: very green lawn 636 1g + 1g + 1g Ca (OH) 2 / 926c / 1h pale (gray tone)
minerals: # 18 + # 26 i production method: light lawn green 637 1 g + 1 g + 1 g SiC / 926 C / 1 h (gray tone)
mineral: # 11 / production method: light green lawn 638 2 g + Na2CO3 2 gi 0 # 871 OC + 1 hr at 871 C (gray tone) irradiated with radiation y at 550.22 Mrad
mineral: 53 / production process: light green 639 1% 53 mixed with glass paste and the between mint green everything is fused to 1315 oC and green lawn
#
darker 640 radiation irradiated γ at 9.88 Mrad
mineral: # 52 i production process: emerald green + 641 2g + Na2CO3 2g / 0 # 982c + 1h to 982c accented as pale emerald green
mineral: 52 production process: emerald green 642 2 g + Na2CO3 2 gi Ot 926 C + 1 h at 926 C much more intense irradiated with W radiation at 64.7 Mrad than light emerald green
mineral: # 34 / production method: pale emerald green 643 100 g + HCl 100 ml I soaking: 5 m. I drying
natural / 032 C: 50 g + NH4OH 5 ml / sec
natural chage: .1 g + 50 cc poly-resin
transparent ester + 1% catalyst / broya
manual handling i deposit in a closed container of a
lid and placed in an oven for
plastics at 37 C until hardening
mineral: 17 J production process: emerald green a 644 2 g + HCl 20 ml + HNOx 5 ml i soaking: 6 d J little + clear that the separation of the liquid and the solid i dry green emerald clear natural / irradiated with radiation γ at 65.65
mrad
mineral: # 8 I production process: light emerald green 645 irradiated neutron radiation powder
during 2,000 sec at 1012 neutrons i cm2 i
dry; then, covered with 20 ml of developer
D19 photograph of Kodak / color of
liquid
mineral: 17 production process: a) emerald green 646 2 g + HCl 20 ml + HNO3 5 ml / soaking: 6 d / clear b) yellow green separation of liquid and solid / drying very clear natural i color of a) liquid b) solid
mimal: 34 / production process: a) emerald green 647 stone covered with 1000 ml clear acetic acid b) dark gray i natural drying i crystal picking
on the stone: 2 g crystals + H3PO4 20 ml /
soaking: 3 days drying on a hotplate
(hum.) / color of a) liquid b) solid
mineral: # 99 i production process: bright emerald green 648 2 g + Na2COz 2 gi 0 # 1037 OC + 1 hr at 1037 C
mineral: # 17 / production process: a) emerald green 649 3 g + HNO3 50 ml / soaking: 6 d / separation b) pale apple green liquid and solid / natural drying /
color of a) liquid b) solid
mineral: # 60 / production process:
2 g + Na2CO3 2 g: emerald green 650 0 # 871 C + 1 h at 871 C
# 651 0 # 1037 C + 1 h to 1037 C
mineral: # 103 J production process: a) emerald green 652 4 g + HCl 20 ml I soaking: 24 hi separation b) gray brown liquid and solid / drying on plate
heating / color of a) liquid b) solid
mineral: 104 / production process: emerald green 653 4 g + H3PO4 20 ml / soaking time: 3 days / drying
on hot plate
mineral: # 34 i production process: emerald green + 654 100 g + HCl 100 ml i soaking: 5 m. / intense drying on a hot plate: .50 g + NH4OH 5 ml
i natural drying: .1 g + 50 cc resin
transparent polyester + 1% catalyst I
manual grinding / storage in a closed container
a lid and placed in an oven for
plastics at 37 C until hardening
mineral: # 69 / production process: emerald green 655 2 g + Na2CO3 2 g / 0 # 982 C + 1 h at 982 C intense and dark J irradiated with X radiation at 423.88 Mrad
mineral: 60 / production process: emerald green 656 2 g + Na2CO3 2 g / 0 # 926 C + 1 h at 926 C much accented irradiated with radiation w at 424.7 Mrad
mineral: # 17 / production process: a) emerald green 657 3 g + HCl 50 ml / soaking: 6 d / drying naintense b> yellow turquoise / color of a) dried liquid natural canary very bright b) solid dried on hotplate
mineral: # 20 / production process: emerald green 658 2 g + Na2CO3 1 g / 926 C / 1 h intense
mineral: # 30 / production process: a) emerald green 659 4 g + HNOs 50 ml / soaking: 2 h I intense separation b) green liquid and solid in 6 parts: a) light apple c) liquid green pure: natural drying; b) the olive liquid (light pure tone: drying on a sand bath, c) the yellow liquid) d) olive green and some solid; d) solid: drying nae) light green (light turel, e) solid: drying on blue saton bath) f) green ble; f) the solid resulting from c): olive natural drying (light tone J color of a, b, c, d, e and yellow) [less intense than c))
mineral: # 54 / production process: emerald green 660 1 g + Na2CO3 1 g / 982 C / 1 h intense
mineral: '* 34 / production process: emerald green + 661 stone covered with 1000 ml dark acetic acid as green / natural drying / emerald crystal levitation pronounced on stone / rayon irradiated crystals
ment @ at 64.7 Mrad
mineral: # 34 / production process: emerald green + 662 stone covered with 1000 ml intense acetic acid / natural drying / crystal picking
on the stone: I g crystals + NH + OH 4 ml /
natural drying: .20 g + 50 cc resin
transparent polyester + 1% catalyst /
manual grinding / molding f hardening /
irradiated with electronic radiation at 305,082
rad
mineral: # 34 / production process: emerald green + 663 stone covered with 1000 mi clear acetic acid as green / natural drying / emerald crystal picking very bright on the stone i the crystals are irradiated at
electronic radiation at 302,831 rad
mineral: # 22 f production process: a) emerald green 664 4 g + NHO3 100 ml / soaking: 2 em. i separatrès intense tion of the 1st liquid and the solid i addition of b) very bright blue I HNO5 100 mi to the same solid I separation of the 2s green acute turquoise liquid and the solid I drying in desiccator c) intense green, half of the 2nd liquid / natural drying of solid / toyen between green color of a) 1st liquid b) 2nd liquid lawn and green c) solid of Paris
mineral: # 95 / production process: emerald green 665 3 g + HC1 BO ml / soaking: 2 wk. ; A large amount of liquid and solid i drying on the emerald green hot plate / the liquid is irradiated with very bright radiation @ 64.7 Mrad
mineral: # 34 / production process: emerald green + bright 666 stone covered with 1000 mi acetic acid and intense as the natural drying / s removal of the emerald green crystals very much on the stone: 2 g crystals + 4 g intense Portland cement + 6 cc concrete polymer + 0.18 cc
catalyst + 1.50 thousandth of 9 cobalt 6% /
manual grinding / molding / hardening / ir
Radiated to radiation # at 18.85 Mrad
mineral: 27 t production process: emerald green 667 4 g + H2PO4 50 ml / soaking: 2 wk. / powerful drying on hot plate (hum.)
mineral: # 50 + # 98 / production process: emerald green 668 10 g + 10 g + Na2CO3 20 g / 982 C powerful and dark / 1 hr
mineral: # 181 / production process:
2 g + Na2CO3 2 g: emerald green very 668.1 871 oC / 3 h powerful # + dark 668.2 871 C / 8 h
mineral: # 81 + * 98 / production process: very emerald green 669 1 g + 1 g + Na2CO3 3 g / 871 C / 1 hr powerful
mineral: # 181 / production process: emerald green 670 2 g + K2CO3 3 g / 0 # 871 C extremely powerful
mindral: * 34 / production process: dark emerald green 671 stone covered with 1000 mi acetic acid
/ natural drying / crystal picking
on the stone: 5 g crystals + NH4OH 25 mi
/ natural drying / radiation irradiation @ to
424.7 Mrad
mineral: # 54 / production process: emerald green + 672 1g + K2CD3 3g / 0 # 982 Darker than dark emerald green
mineral: * 81 / production process: very emerald green 673 2 g + Na2CO3 2 g / 0 # 982 C + 1 h at 982 C powerful and dark
minerals: # 150 + 98 / production process: emerald green som 674 10 g + 10 g + Na2CO3 20 g / 0 # 1121 oC ber going to black
mineral: # 107 / production process: very emerald green 675 1g + Na2CO3 2g / 0 # 982 C bright (blue tone)
mineral: # 24 / production process: very emerald green 676 1g + 6.50g glass powder (powerful spruce pine (blue tone) batch) / manual grinding / deposit on a plate
I ceramic biscuit J heating in a
1 oven of 0 # 1000 C in normal atmosphere
I slow cooling in the furnace increases a little 677 irradiated with radiation Y to 9.88 Mrad
mineral: # 81 / production process:
2g + K2CO3 g: emerald green (tone 678 0 # 926 C blue) + saturated and dark as the emerald green extremely powerful # still + intense 679 0 # 982 C
Mineral: 112T production process:
2 g + Na2CO3 2 g: emerald green (tone 680 0 # 982 C + 1 h at 982 C blue) extremely powerful # intensifies 681 0 # 1037 C + 1 h at 1037 C
mineral: # 54 / production process: emerald green (tone 682 1g + K2CO3 2g / 0 # 982c blue) + darker than black emerald green (blue tone)
mineral: # 5 I production method: light khaki green 683 2 g + Na2CO3 2 g / Otg82 C + 1 h at 982 C
mineral: # 6 / production process:
2 g + Na2CO3 2 g: light khaki green 684 982 C / 1 h
# 685 1037 C / 1h
mineral: # 2i / production process: khaki green 686 2 g + K2CO3 2 9/0 # 815 C
mineral: 5, production process:
50 g + HCl 200 ml or asbestos covered with
HCl / soaking: 1 week / drying on plate
heating: 3 g + Na2CO3 4 g: green khaki 687 982 C / 45 min # + dark and green 688 982 C / 55 min
mineral: # 6 / production method: medium khaki green 689 2 g + Na2CO3 2 g / 648 C / 1 h
Minerals: # 14 + # 26 / Production Process: Medium khaki green 690 1.50 g # 14 + .50 g # 26/0 # 1037 C # increased significantly 691 irradiated with electronic radiation at 302,831
rad
mineral: # 5 / production process: green khaki / green 692 50 g + HCl 200 ml or asbestos covered with
HCl / soaking: 1 week / drying on plate
heating: 3 g + Na2CO3 4 g / 982 C / 1 h
mineral: # 26 / production process: dark khaki green 693 1 g + 6.50 g glass powder (spruce pine (yellow reflection) batch) / manual grinding / deposit on a plate
of ceramic biscuit / heating in a
oven of 0 # 1000 C in normal atmosphere / re
slow frodidissement in the oven + dark 694 irradiated with radiation # at 4.94 Mrad
Minerals: # 14 + # 26 / production process: medium green khaki 695 1.50 g # 14 + .50 g # 26/0 # 1037 C / irradiated (brown tone) at the line # to 424.7 Mrad
mineral: # 6 / production process: medium khaki green 696 2 g + Na2CO3 2 g / 0 # 648 C + 1 h at 648 C (orange-brown tone)
mineral: # 6 / prouction method: khaki green accented 697 2 g + Na2CO3 2 g / 482 C / 1 h / irradiated (light gray brown tone) with radiation at 424.7 Mrad
Minerals: 18 + # 26 / production method: very light green 698 1.50 g # 18 + .50 g # 26 / milled and moistened [near beige] with water until consisitance dåte /
704 C / 1 h
minerals: # 26 + # 29 / production process: very light green 699 1.50 g # 29 + .50 g # 26 / crushed and hu = [quasi beige] mected with water to consistency
paste / 815 C / 1 h
Minerals: # 18 + # 26 / Production Process: Beige Green + Pale 700 1.50 g # 18 + .50 g # 26/898 C / 1 hr Green Beige Light / Irradiated to Scratch # at 550.22 Mrad
Minerals: # 18 + # 27 / Production Process: Beige Green + Pale 701.50 g # 97 + 1.50 g # 18 / Ot 10.37 C / Irk Light Beige Green X-rayed at 424.7 Mrad
mineral: # 22 / production method: beige green 702 3 g + 20 ml cyanide solution
(95% distilled water + 5% KCN) / natural drying
the solid is irradiated with radiation # to
424.7 Mrad
mineral: 1 / production method: light brown green 703 3 g + H2SO4 50 ml / soaking: 2 wk. / drying
on hot plate
mineral: # 50 / production method: green brown 704 4 g powder deposited on a piece of steel
stainless steel measuring 1 "x 1" / 760 oC i 20 min
I immediate withdrawal
minerals: # 26 + 29; production process: brown green 705 1.50 g # 29 + .50 g # 26/1093 C / 1 h + accentuated 706 1.50 g # 29 + .50 g # 26/1093 C / 4 h still + accented 707 1.50 g * 29 + .50 g $ 26/1093 C / 8 h
mineral: # 77 / production method: green brown (reflection 708 1 g + 6.50 g glass powder (spruce pine yellow) batch) / manual grinding i deposit on a plate
of ceramic biscuit / heating in a
oven of 0 # 1000 C in a mormal atmosphere / re
slow cooling in the oven
mineral: # 44 I production process: brown green (709 g 2 g + HCl 20 ml / soaking: 3 days / drying on amber) clear hotplate: .20 g + 50 cc resin
transparent polyester + 1% catalyst /
manual grinding / hardening / irradiated at
electronic radiation at 305,082 rad
Mineral value: 26 + 96, production method: brown green 710 1 g + 1 g / 1093 C / 45 min (accented gray tone)
mineral: # 34 / production process: green bottle 711 stone covered with 1000 ml acetic acid foam / natural drying / crystal picking
on the stone / the crystals are heated
148 C / 10 min
Minerals: # 16 + # 53 + # 98 / Production Process:
* 53 is warmed 0 # 760 C: 8 9 + 96 9 # 98 J
815 C / 1 h: .50 g + .50 g # 16: green foam 712 -871 C / 1 h
# 713 -926 C / 1 h
Minerals: # 53 + # 98 / Production Process: Moss green 714 &# 53 is heated 0 # 760 C; 8 g + 96 g # 98 /
815 C / 1 hr: .50 g + Na2CO3 .50 g / 871 ° C
/ 1 h
mineral: # 67 i production process: foam green 175 2 g + Na2CO3 2 g / 0 # 482 C + 1 h at 482 C
/ radiation irradiated γ at 63.88 Mrad
mineral: # 64 / production method: green foam + 716 5 g + NH4OH 25 ml / natural drying / intense radiation irradiation γ at 64.7 Mrad
Minerals: # 103 + # 98 / production method: medium green 717 1 g + 1 g / 1093 C / 20 min
mineral: # 67 / production method: moss green 718 2 g + Na2CO3 2 g / 0 # 593 C + 1 h at 593 C accented / irradiated with gamma radiation; at 63.88 Mrad
mineral: * 67 J production process: green foam 719 2 g + Na2CO3 2 g I 0 # 537 C + 1 h at 537 C accentuated and dark / irradiated with gamma radiation; to 424.7 Mrad
mineral: # 67 / production process: very foamy green 720 2 g + Na2CO3 2 g / 0 # 537 C + 1 h at 537 C pronounced (light / radiation irradiated γ at 64.7 Mrad blue tone)
mineral: # 64 i Production method: lichen green 721 1 g + NH4OH S ml / natural drying 4- + dark 722 1 g + NH4OH 20 ml / natural drying
mIneral: 28 d Production method: dark lichen green 723 2 g + Na2CO3 2 g / 482 C / 1 h [near black]
mineral: # 56 / production method: light green mother of pearl 724 1 g + Na2CO3 2 g J 0 # 982 C middle between lichen green and olive green, + olive green than lichen) light green mother of pearl 725 1 g + Na2CO3 3 4, g / Ot 982 C middle between lichen green and olive green, + green lichen green]
mineral: # 67 / production method: light green grind 726 finely ground and heated powder of
Ot 648 C: .50 g + HNO3 15 ml / soaking:
2 days / drying on a hot plate: .20 g +
50 cc transparent polyester resin + 1%
catalyst / manual grinding / molding /
hardening / irradiated with electro radiation
at 305,082 rad354
mineral: * 67 J production process: 727 very finely ground and heated gray green of 0 # 593 OC: 50 + accentuated as g + HNO3 15 ml i soaking: 2 jf drying on pale gray green heating plate: .20 g + 50 cc resin of
transparent polyester + 1% catalyst /
manual grinding / molding / hardening i ir
radiation-free at 305,092rad
mineral: # 6 / production method: light gray green 728 4 g + H2SO4 200 ml / soaking: 4 wk. / drying
heating on hot plate / irradiated with rayon
electronically at 302,831 rad
mineral: # 34 / production method: gray green 729 100 g + HNO3 100 ml / soaking: 5 m. / drying
natural age / 0 # 204 C
mineral: # 42 / production process: green gray + intense 730 1 g + l cc white synthetic enamel paint
transparent for auto / manual grinding i ap
on a piece of body sheet
measuring 1 "x 1" / radiation irradiated γ at
10 Mrad
mineral: # 8 J production process: dark gray green 731 2 g + N2CO3 2 g / 0 # 926 C + 1 h at 926 C
mineral: # 6 / production method: green gray (reflection 732 4 g + H2SO4 200 ml / soaking: 4 weeks / sechabrun) + blade as hotplate age 1 irradiated with rayon gray medium γ at 550.22 Mrad (brown tone)
mineral: # 4 J production process: black green 733 2 g + Na2CO3 2 g / 0 # 982 C + 1 hr at 982 C
/ radiation irradiated γ at 424.7 Mrad
Minerals: # 53 + # 98 / Production Process: Black Green 734 1g + 1g + Na2CO3 2g / 871c / 1h
Minerals: # 53 + # 98 Production Process: Black Green 735 1 g + 1 g + Na2CO5 3 gi 871 C / 1 hr
736 g + I g <RTI ID = 82
mineral: &num; 97 i production process: black green (748 tone 1 g + 1 cc gray white synthetic enamel paint) transparent for auto 1 manual grinding J ap
on a piece of body sheet
measuring 1 "x 1" / radiation irradiated &gamma; at
57.4 Mrad
mineral: &num; 9 i production process: olive green + light 749 4 g + HC1 80 ml i soaking: 2 wk. separates the olive green from the liquid and solid on a clear heating plate / irradiated with gamma radiation;
at 70.4 Mrad
mineral: 68 / production process: light olive green 750 0 # 1093 C / irradiated & gamma irradiated powder;
at 64.7 Mrad
mineral: &num; 11 / production method: light olive green 751 6 g + HCl 50 ml / soaking: 2 wk. / intense drying on a hot plate
mineral: &num; 9 i production process: a) light olive green 752 4 g + HCl 80 ml / soaking: 2 wk. / separab) olive green + tion of liquid and solid I drying on intense hot plate / color of a) solid
b) liquid
minerals: &num; 26 + &num; 29 I production process: light olive green 753 1.50 &num; 29 + .15 g &num; 26/898 C / 1h
# 754 1.50 g + 1.50 g / 915 C / 1 h
mineral: &num; 6 i production method: green [green genus 755 4 g + HCl 100 ml / soaking: 2 wk. / olive drying] on a hotplate
mineral: &num; 6 / production method: olive green 756 250 g + HCl 1650 ml in a 2000 ml beaker
or asbestos completely covered with HCl in
a container in height / soaking: 1 wk. /
hot plate drying (formation of 2
superimposed layers of color) the layer
depth is irradiated with elec
tronic to 162,431 rad
mineral: &num; 11 i production process: olive green 757 2 g + Na2CO3 2 g / Ot 926 OC + 1 h at 926 C
Minerals: 18 + # 26 / Production Process: Olive green 758 1.50 g &num; 18 + .50 g &num; 26/1037 c: .25 g +
H2SO4 20 ml / soaking: 3 days / drying on
hotplate
Minerals: 26 &# 29 / Production method: olive green 759 1.50 g &num; 29 + .50 g &num; 26/1037 C / 1 h
mineral: &num; 50 I production process:
4 g powder deposited on a piece of steel
stainless steel measuring 1 "x 1": green Egenre green 760 760 OC / 3 min / immediate withdrawal olive) 761 760 CI 6 min I immediate withdrawal
mineral: &num; 56 / production process:
2 g + Na2CO3 2 g: olive green 762 0 # 926 C + 1 h to 926 C
# 763 0 # 982 C + 1 h to 982 C
mineral: &num; 59 / production method: olive green 764 2 g + Na2CO3 2 g / 0 # 926 C + 1 h at 926 C
mineral: * 77 I production process:
2 g + Na2CO3 2 g: olive green 765 0 # 815 C + 1 h at 815 C + dark 766 Ot 871 C + 1 h at 871 C still dark 767 Ot 926 C + 1 h at 926 C still dark 768 0 # 982 C + 1 h to 982 C still + dark 769 0 # 1037 C + 1 h to 1037 C
mineral: i87 X production process: olive green 770 0 # 704 C: 3 g + HCl 25 ml / soaking: 4-5 days
/ drying on a hot plate
mineral: t54 / production process: olive green + dark 771 1% is mixed with glass paste and the all olive green is fused at 1315 C / irradiation at
radiation &gamma; at 4.94 Mrad
mineral: &num; 8 / production method: medium olive green 772 0 # 1093 C / radiation irradiated & gamma powder;
at 424.7 Mrad
mineral: 28 production process: genus olive green 773 5 g + NH4OH 25 ml / natural / irradiated drying medium and intense at radiation &gamma; at 424.7 Mrad
minerals: &num; 26 + 29 production process: medium olive green 774 1.50 g &num; 29 + .50 g &num; 26 / / 1010 C / 1 hr
Minerals: # 5 + # 64 / Production Process:
&num; 5 is heated to 0 # 1037 C: 50 g + HCl 200 ml
or asbestos covered with HCl / soaking: 1
wk. J hot plate drying: olive green 'average 775 1 g + 0.2812eg &num; 64 + 0.14061 MgO I grinding olive green a little 776 1g + 0.28122 g &num; 64 + K2CO3 0.28122 9 / + pale as the green grinding olive medium # medium olive green 777 1 g + 0.28122 g &num; 64 / grinding
mineral: &num; 6 / production process: olive green + IN 778 4 g + HCl 100 ml / soaking: 2 wk. / drying tense and accentuated on heating plate / irradiated with radiation
&gamma; at 190.22 Mrad
mineral: t15 / production process: intense olive green 779 30 g + HCl 100 ml / soaking: 24 h / drying
in an oven at 130 C
mineral: &num; 15 i production process: pronounced olive green 780 3 g + HCl 20 ml + 5 ml water / soaking: 4-5 days
/ drying on a hot plate
minerals: &num; 18 + * 26 1 production process: bright olive green 781 1 g + 1 g + 1 g SiC / 926 C / 1 h / re
cold / 982 C / 15 h + 30 min
mineral: &num; 22 / production method: intense olive green 782 4 g + HNO3 100 ml f soaking: 2 wk. f separated
of the liquid and the solid / drying of the
1st liquid in the desiccator / addition to the same
llde of HNO3 100 mi I soak: 2 wk. / sep
ration of the 2nd liquid and the solid I drying
desiccator of the 2nd liquid; natural drying
solid / 1st 2nd liquid is irradiated with rayon
ment &gamma; at 64.7 Mrad
mineral: &num; 87 / production method: olive green 783 15 g + HCl 100 ml / soaking: 24 h / pronounced drying on heating plate
mineral: &num; 7 / production method: intense olive green 784 2 gt Na2CO3 2 g / 0 # 815 oC + 1 hr at 815 C
mineral: &num; 9 / production method: olive green very 785 .81 g + Na2CO3 1.31 g / 926 C / 1 h / irraintense dye au ravonnement &gamma; at 65.65 Mrad
mineral: &num; 15 / production method: olive green very 786 40 g + HCl 100 ml / soaking: 5 m. / intense natural drying
mineral: &num; 15 I production process: olive green plus 787 40 g + HCl 100 ml / soaking: 5 m. / intense drying as natural green / irradiated with radiation &gamma; at 424.7 very intense olive Mrad
mineral: &num; 26 / production process: olive green + dark 788 1 g + .74 g mold shell powder; that the olive green 926 c / 1 h / radiation irradiated &gamma; at very intense 70.4 Mrad
mineral: &num; 27 I production process: dark olive green 789 2 g + Na2CO3 2 g / 0 # 871 C + 1 h at 871 C
mineral: &num; 50 / production method: dark olive green 790 .45 g + Na2CO3 .45 g / deposit on a glass pane
Sure 1 "x 1" x 1/8 "/ 0 # 926 C / Cooled
slow in the oven
mineral: &num; 50 / production process: dark olive green 791 150 y glass paste (sodalime) is collected
in the melting state in the furnace (1200 C)
on a rod of metal J 2 g &num; 50 are saupou
dredged on the surface of the glass I then, the whole thing is
reintroduced into the furnace and melted to the
flame at 1200 C / then, the collection is deta
of the metal rod
mineral: &num; 56 / production process: dark olive green 792 1 g + K2CO3 1 g / 0 # 982 C
minerals: t73 + &num; 76 1 production process: olive green slightly 793 0.14061 g &num; 73 irradiated with radiation r at 2.26 + pale green Mrad + 0.14061 g dried pork blood irradiated dark olive with radiation y at 2.26 Mrad + 0.14061 g in
digo irradiated with radiation W at 2.26 Mrad +
0.14061 g &num; 76 irradiated with radiation # at 2.26
Mrad / grinding
mineral: &num; 73 J production process: olive green slightly 794 0.14061 g &num; 73 irradiated with X-radiation at 2.26 + pale as green Mrad + 0.14061 g dried pork blood irradiated dark olive with radiation y at 2.26 Mrad + 0.14061 g in
digo irradiated with radiation at 2.26 Mrad +
Na2CO3 0.28122 g / grinding
mineral: &num; 73 f production process: dark olive green 795 0.14061 g &num; 73 irradiated with radiation y at 2.26
Mrad + 0.14061 g irradiated dried pork blood
at X radiation at 2.26 Mrad + 0.14061 g in
digo irradiated with radiation at 2.26 Mrad /
grinding
mineral: &num; 6 I production process: olive green + bright 796 250 g + HCl 1650 ml in a 2000 ml beaker as olive green or asbestos covered with HCI in a dark container in height and soaking: 1 wk. / drying on
hot plate (formation of 2 layers of
superimposed colors) l the deep layer
deur is irradiated with radiation # at 550.22
mrad
mineral: &num; 22 / production process: bright olive green and 797 4 g + HCl 100 ml / soaking: 2 wk. / separation of liquid and solid / drying on
hotplate / radiation irradiated #
at 424.7 Mrd
mineral: t87 I production process: dark olive green 798 3 g + HCl 25 ml / soaking: 3 d / drying on and intense hotplate / irradiated with radiation #
at 424.7 Mrad
mineral: &num; 91 I production process: dark olive green 799 6 g stones + 27.4 g Portland cement +
13 cc water / mixing / molding I harden
radiation irradiated at 18.85 Mrad
mineral: &num; 95 / production process: dark olive green 800 0 # 1037 C: .30 g + HCl 50 ml / soaking: 2
wk. J separation of liquid and solid i
drying on hotplate / irradiated at
radiation at 424.7 Mrad
mineral: &num; 22 / production method: olive green (light 801 4 g + H2SO4 100 ml J soaking: 2 weeks / mint green sépaton) ration of the liquid and solid / drying on + dark than the heating plate / irradiated at W green olive intanse radiation at 64.7 Mrad (mint green tone)
mineral: &num; 50 i production process: light olive green 802 150 g glass paste (sodalime) is collected yellow) in the melting state in the furnace (1200 C)
on a metal rod J .45 o'50 is saupou
dredged on the surface of the glass J then, the whole thing is
reintroduced into the furnace and melted to the
flame at 1200 C / then, the collection is de
stained with metal rod
mineral: &num; 15 / production method: olive green (tone 803 0 # 537 C: 3 g + HCl 25 ml / soaking: 3 d / yellow) drying on hotplate
Mineral: 15 ° C Production method: olive green (804 g + HCl 25 ml i soak: 5 ji drying on yolk) [different hotplate from above]
mineral: &num; 61 J production process: olive green (tone 805 2 g + Na2CO3 2 g / 0 # 926 C + 1 h at 926 C janue)
mineral: &num; 22 J production process: olive green (tone 806 g + NHO3 100 ml tempering: 2 weeks I separajaune) a little + tion of the 1st liquid and the solid f drying in the dark 1 of the first liquid i added at the same
NHO3 lide 100 ml J soaking time: 2 weeks i separated
ration of the 2nd liquid and the solid J drying at
desiccator of the 2nd liquid i natural drying of
solid / the solid is irradiated with radiation
# to 424.7 Mrad
mineral: 50 ° C product process: olive green (light 807 .45 g + Na2CO3 .45 g) deposit on a yellow meton pane) a little safe i "x 1 @ x 1/8 @ i Ot 982 C / chilled + clear that slow cooking in dark olive green (yellow tone)
mineral: &num; 50 / production method: medium olive green 808 150 g glass paste (sodalime) is collected (yellow tone) in the melting state in the furnace (1200 C)
on a metal rod J 1 g * 50 is sprinkled
on the surface of the glass i then, ie everything is re
introduced into the furnace and melted to the
flame at 1200 C / then, the collection is deta
of the metal rod
mineral: &num; 27 I production process: pronounced olive green 809 2 g + Na2CO3 2 gf 0 # 1037 C + 1:45 h at (orange reflection 1037 C / radiation irradiated at 64.7 Mrad located)
mineral: &num; 50 t Production method: dark olive green 810 1 g powder deposited on a glass measuring 1 "(orange reflection x 1" x 1/8 "/ 0 # 815 C / localized slow cooling) in the oven
mineral: &num; 54 / production process: light olive green 811 1% is mixed with glass paste and the amber tone) everything is fused at 1315 C / irradiation at
radiation at 9.88 Mrad
mineral: &num; 15 / production method: olive green (tone 812 3 g + NHO3 5 ml + HCl 20 ml / soaking: 4-5 d brown) / drying on hotplate
mineral: &num; 55 i production process: olive green (tone 813 2 g + Na2CO3 2 g / 0 # 815 C + 1 hr at 815 C
minerals: &num; 73 + &num; 76 i production process: olive green (tone 814 1 g &num; 73 + 0.14061 g indigo irradiated with rayon) lighter than y 2.26 Mrad + 0.14061 g t76 f milling medium olive green (your brown tone)
mineral: &num; 67 J production process: medium olive green 815 593 C / 1 h / irradiated with radiation # to (gray tone) 424.7 Mrad
mineral: &num; 56 / production process: light green pearl 816 1 g + Na2CO3 2 g / 0 # 982 oC motoyen between olive green and lichen green
mineral: &num; 70 I production process: semi-green between 817 1 g + Na2CO3 2 gi and 982 C olive green and phthalo green
mineral: &num; 54 i production process: dark green semi-detached 818 1% is mixed with glass paste and the between green apple and $ all is fused to 1315 C olive-green
mineral: &num; 27 / production process: green intermediate between 819 2 g + H3PO4 20 mi i soaking: 3 i olive and green drying on sand bath i irradiated with y-apple radiation + intense and 424.7 Mrad dark than green intense and focussed
mineral: &num; 53 i production process:
- 4 g + Na2CO3 4 g: olive green foam 820 0 # 871 C
# 821 0 # 982 C
- # 4 g + Na2CO3 3 g:
# 822 0 # 871 C
# 823 0 # 982 C
- # 4 g + Na2CO3 2 g:
# 824 0 # 926 C
# 825 0 # 982 C
- # 4 g + Na2CO3 1 g:
# 826 0 # 926C
# 827 0 # 982 C 1 - 4 g + Na2CO3 4 g:
# 828 0 # 871 C
# 829 0 # 982 C
- # 2 g + Na2CO3 4 g:
# 830 0 # 871 C # 831 0 # 982 C
I - 1 g + Na2CO3 4 g:
# 832 03871 C
# 833 0 # 982 C
- # 2 g + Na2CO3 3 g:
# 834 0 # 926 C
# 835 0 # 982 C 1 - 1 g + Na2CO3 3 g:
# 836 0 # 926 C
# 837 0 # 982 C # - - 3 g + Na2CO3 1 g:
838 0 # 926 C
839 0 # 982 C
I - 3 g + Na2CO3 2 g:
1 840 0t871 oC
# 841 0 # 982 C
# - 1 g + Na2CO3 1 g:
# 842 0 # 926 C
# 843 0 # 982 C
mineral: &num; 53 I production process:
3 g + Na2CO3 4 g / 926 C: between red 844 15 min brown and olive green foam #
# olive green moss 845 30 min + intense # still + # 846 60 min # still + 847 1:30 h
minerals: &num; 53 + 93; production process: olive green foam 848 .50 g + .50 g + Na2CO3.50 g / 926 C
/ 1 h
Minerals: # 53 + # 98 J Production Process: Olive Green Moss 849 1g + 1g / 0 # 926C / Cooling: Intense .50g + Na2CO3 1g / 0 # 926C
Minerals: &num; 50 + &num; 98 i Production Method: Pale Apple Green 850 .45 g + 45 g Deposit on a pale yellow-colored glass pane 1 "x 1" x 1/8 "/ 0 # 787 C / cooling
slow in the oven
mineral: &num; 11 / production method: light apple green 851 2 g + Na2CO3 2 g / 0 # 815 C + 45 min at
815 C
mineral: &num; 11 I production process: light apple green 852 stone irradiated with X-radiation at 65 Mrad: and bright .30 g irradiated powder + Na2CO3 .50 g 1
926 C / 1 h
mineral:> 100 I production process: a) light apple green 853 60 g + H3PO4 100 ml / soaking: 3 wk. i sepab) light green mother of pearl ration of liquid and solid J drying c) light gray on hot plate (hum.) i color of
a) the first layer of liquid on the surface
b) 2nd layer of liquid c) solid
mineral: &num; 101 / production method: a) light apple green 854 40 g + H3PO4 100 ml / soaking: 3 wk. / b) light mint green separation of liquid and solid / sec) gray brown chage on hot plate (hum.) I color
a) ler liquid b) 2nd liquid t) solid
mineral: 17 / production process: dark apple + green 855 2 g + HNO3 15 ml + HCl 10 ml / trmpage: 6 d and dark as the I separation of liquid and solid i drying green apple light natural / irradiated with radiation at 65.65
mrad
mineral: +5 / production process: a) apple green 856 250 g + HCl 1650 ml in a 2000 ml beaker b) orange (light or asbestos covered with HCl in a green container) c) orange in height / soaking: 1 week I drying on clear hotplate (formation of 3 layers of
superimposed colors! J color of the layer
a) at depth b) terraced c) at the surface
mineral: * 5 / production process: apple green 857 0t 537 OC: 3 9 + HCl 25 ml J immediate drying
on hot plate: .3 g + 50 cc resin
transparent polyester + 17. - Catalyst I
manual grinding i molding J filing in a con
holding closed a lid and deposited in a
oven for plastics at 37 C up to hard
# cissement
# green apple 858 3 g + HCl 5 ml + 20 ml water / soaking: 5 d
drying in an oven at 37 OC: .3 9 + 50 cc
transparent polyester resin + 1%
catalyst i manual grinding / molding J deposit
in a closed container with a lid and
placed in an oven for plastics at 37 QC
up to apple green 859 3 g + HCl 15 ml + 10 ml water / soaking: 5 days
| / drying in an oven at 37 C .3 g + 50
cc transparent polyester resin + 10
Catalyst drops / manual / soft grinding
lage / deposit in a closed container of a neck
and placed in an oven for
# ques at 37 C until durrissement # apple green 860 3 g + HCl 15 ml + 10 ml water / soaking: 5 d
| / drying in an oven at 37 C: .3 g + 50
| cc transparent polyester resin + 8
drops catalyst / manual grinding f soft
lage I deposit in a closed container of a neck
and placed in an oven for plasti
# ques at 37 C until hardening # apple green 861 3 g + HCl 20 ml + 5 ml water / soaking time: 5 days
| / drying in an oven at 37 C: .3 g + 50
| cc clear polyester resin + 17.
catalyst I manual grinding I molding /
deposit in a closed container with a lid
and deposited in an oven for plastics to
# 37 C until hardened # apple green 862 3 g + HCl 25 ml / soaking: 5 d / drying in
an oven at 37 C: .3 g + 50 cc resin of
transparent polyester + 17. catalyst 1
manual grinding I molding I the container is
closed during hardening green apple 863 3 g + HCl 20 ml + 5 ml water I soaking: S j I
drying in an oven at 37 C: .3 g + 50 cc
transparent polyester resin + 1%
catalyst / manual grinding I molding
# container is closed during hardening # apple green 864 3 g + HCl 15 ml + 10 ml water / soaking: 5 jf / drying in an oven at 37 C: .3 g + 50
cc transparent polyester resin + 1%
catalyst I manual grinding J molding I the
# container is closed during curing # apple green 865 3g + HCl 10ml + 15ml water / soaking: 5d
I drying in an oven at .37 C: .3 g + 50
cc transparent polyester resin + 1%
catalyst / manual grinding f molding I the
container is closed during hardening green apple 866 3 g + HC1 5 mi + 20 ml water / soaking: 5 days
1 drying in an oven at 37 C: .3 g + 50
cc transparent polyester resin + 1%
catalyst I manual grinding I molding I the
container is closed during hardening
mineral: &num; 9 / prodction method: apple green 867 .81 g + Na2CO3 1.31 g / 926 C / 1 h
mineral; * 22 / production process: a) apple green 868 3 g + 20 ml cyanide solution (KCN 5% b) turquoise green + 95% distilled water) i natural drying /
color of a) liquid b) solid
mineral: * n7 I production process: apple green 869 2 g + K2CO3 2 g / 0 # 982 C
mineral: &num; 28 J production process: a! apple green 87 2 g + HCl 25 ml f natural drying í color b) lemon yellow a) liquid b) solid clear and bright
Minerals: # 50 + # 98 / production method: apple green 871 2 g + 2 g / 704 C / 1 hr
Minerals: i50 + &num; 98 / production process: apple green i orange 872 1 g + 1 g + 6.50 g glass powder (caramel spruce (pine batch reflection) f manual grinding I deposit on a jane) biscuit ceramic plate / heating in
an oven of 0 # 1000 C in a normal atmosphere /
slow cooling in the oven
mineral: &num; 50 / production process: apple green J orange 873 1 g powder + 27.4 g Portiand cement / yellow 1 gray + 13 cc water I manual grinding i ase molding
curing i addition of 1 g powder on the
dried cement i 0 # 926 C
mineral: 50f production process: apple green 874 1 g poundre + Na2CO3 1 g / crushed and
spread over china / 0 # 760 C

Minerals: # 50 + # 54 / Production Process: Apple Green 875 27.4 g Portland Cement + 13 cc Water +
Na2COz ig + I g &num; 54 f manual / soft grinding
aging / curing / adding to the surface of
dried cement of 3 g &num; 50/0 # 926 C
Minerals: # 50 + # 15 / Production Process: Green Apple I Orange 876 27.4g Portland Cement + 5g + 15c + 13cc
water I manual grinding J molding i harden
addition to the surface of the dried cement of
3 g &num; 50/0 # 926 C
mineral: &num; 77 i production process: a) apple green 877 8 g + H3PO4 100 ml dipping: 4 years / formab) white c) 4 layers of superimposed colors, medium emerald, the first 2 being liquid and the 2 in d) green lawn depth are solid 1 separation of the 4 dark (gray tone) layers / drying on hot plate (hum.)
J color of a) liquid on the surface b) 2e
liquie c) 1st layer of solid d) 2nd layer
solid
mineral: i "8 X production process: apple green + bright 878 2 g + HCl 25 ml / natural drying / the liquid that the apple green is irradiated with radiation y to 64.7 Mrad
mineral: &num; 9 / production process: green apple + dark 879.81 g + Na2CO3 1.31 g / 926 C / 1 hr / irraque apple green with electronic radiation at 305,200 rad
mineral: &num; 7 / production process: apple apple green 880 2 g + HNO3 20 ml + HCl 5 ml / soaking: 6 days between clear and separation of liquid and solid I drying natural medium I solid is irradiated to radiation
there to 425.65 Mrad
mineral: &num; 64 / production method: medium green apple 881 2 g + H2SO4 20 ml / natural drying / irradiated
at radiation # at 424.7 Mard
mineral: 17 / production method: medium green apple 882 2 g + HNO3 20 ml + HCl 5 ml I soaking: 6 if and lively separation of liquid and solid / drying
natural / the liquid is irradiated with rayon
ment # to 425.65 Mard
mineral: &num; 55 / production method: medium green apple 883 4 g + HNO3 10 mi / soaking: 2 wk. 1 separates the liquid from the liquid and the solid from the
1st liquid in the desiccator / addition to the same o
HNO3 lide 100 mi I soaking: 2 wk. i separated
2nd liquid and solid / drying
desiccator of the 2nd liquid I natural drying of
solid / 1st 2nd liquid is irradiated with radiation
# to 424.7 Mrad
mineral: # 11 / production process: bright apple green 884 2 g + Na2CO3 2 g / 0 # 871 C + 1 h at 871 C /
irradiated with electronic radiation at 302,831
rad
mineral: * 17 / production process: a) bright apple green 585 12 g + HCl 40 ml / soaking: 3 days J separation b) apple green very 1st liquid and solid / natural drying vivid green green / adding HC ! 100 ml to the same solid / pale trem page: 3 d J separation of the 2nd liquid and the
solid / drying on 2nd li sand bath
quide / color of the ai 2nd liquid b) ler liqui
of this solid dried naturally
mineral: &num; 17 / production process: bright green apple B86 12 g + HNOo 40 ml / soaking: 3 h / separation
liquid and solid / adding to the same
HNO3 solid 40 ml / soaking: 1 day separates
second liquid and solid I added to
same solid of HNO3 40 ml f soaking: 5 days
separation of the 3rd liquid and the solid / secha
ge on sand bath i the 2nd liquid is irra
radiation at 64.7 Mrad
mineral: &num; 24 / production process: a) green apple 887 5 g + HNO3 20 ml / soaking: 15 h / separation b) pale apple green liquid and solid / natural drying of c) apple green liquid / removal of the deposit of material to yellow) d) yellow bottom of the first liquid I natural drying of the deposit [tend veri orangel / addition to the same solid of HNO3 20 ml / tempered
age: 3 days / natural drying of 2nd fluid / neck
a) liquid b) deposit of material at
bottom of liquid ier c) second liquid d) solid
mineral: &num; 71 - production process: very bright green apple 888 4 9 + HCl 50 ml / soaking: 2 wk. / drying
on hot plate
mineral: 17 J production process: a) very apple green, 889 3 g + HCl 50 ml / soaking: 6 d / very bright separation b) yellow liquid and solid J natural drying / canary very bright color of a ) liquid b) solid
mineral: &num; 10 / Production method: dark apple green 890 stone irradiated with radiation # at 65 Mrad:
.76 g irradiated powder + Na2CO3 1.26 g /
926 C / 1 h
mineral: &num; 27 i production process:
2 g + Na2CO3 2 g: dark apple green 891 Ot 982 oC + 1 h at 982 C
# 892 0 # 1037 C + 15 min at 1037 C + dark 893 0 # @ 1037 C + 1:45 h at 1037 C still + dark 894 0 # @ 1037 C + 2 h at 1037 C
mineral: &num; 51 / production process:
- 1 g + Na2CO3 2 g: dark apple green 895 815 C / 1 h
896 871 oC. / 1 h
- # 1 g + Na2CO3 3 g:
# 897 815 C / 1 h
# 898 871 C / 1 h
mineral: &num; 107 i production process: dark apple green 899 X irradiated stone at 65 Mrad:
/ grinding / .25 g powder + Na2CO3 1.25
g / 926 C / 1h
mineral: &num; 108 i production process: very green apple 900 12 g + HNOw 40 ml f soaking: 1 wk. i clear / beige drying on sand bath i irradiated with y radiation and light rosé 423.88 Mrad
mineral: # 23 / production method: apple green (901 4 g + HNOz 50 ml i on deposit, yellowish + pale as boiling / immediately after boiling, light apple green separation of liquid and solid i rest of (yellow tone) 2 separately for 1 week I natural drying
# irradiated with X-radiation at 64.7 Mrad
mineral: &num; 28 / production method: light apple green 902 1 g + NH40H 4 ml / natural drying: .20 g + 50
(yellow tone) cc clear polyester resin + 1%
catalyst J manual grinding i molding y hard
Cement / Irradiated to radiation S to 11.2
mrad
minerals: &num; 50 + * 98 f production process: light apple green 903 .45 g + .45 gf deposit on a glass measuring (yellow reflection 1 "x 1" x 1/8 "/ 0 # 815 C / localized cooling ) slow in the oven
Minerals: &num; 64 + &num; 73 + &num; 76 / production method: apple green (tone 904 0.14061 g * 64 irradiated with radiation y at 2.26 yellow) + påle that Mrad + 0.14061 g &num; 73 irradiated with radiation # the apple green (tone at 2.26 Mrad + 0.14061 g &num; 76 / grinding yellow)
minerals: * 64 + * 73 / production process: apple green (tone 905 0.14061 g &num; 64 irradiated with radiation y at 2.26 yellow) + påle that Mrad + 0.14061 g &num; 73 irradiated with radiation # the apple green (ton at 2.26 Mrad + Na2CO3 0.28122 g / grinding
Yellow)
minerals: &num; 64 + &num; 73 t production process: apple green (tone 906 0.14061 g &num; 64 irradiated with radiation # at 2.26 yellow) Mrad + 0.14061 g &num; 73 irradiated @ with radiation #
at 2.26 Mrad / grinding
mineral: 34 d production process: apple green (tone 907 stone covered with 1000 ml yellow acetic acid) / natural drying / crystal picking
on the stone: 5 g crystals + NH @ OH 25 mi I
natural drying: 1 g + 1 cc printer ink
transparent white box / manual grinding / 1 im
pressure on glossy / irradiated white paper
radiation at 22.8 Mrad
mineral: &num; 27 / production process:
2 g + Na2CO3 2 g: apple green (tone 908 0 # 1037 + 1 h at 1037 C yellow) + darker than dark apple green (yellow tone) # apple green (tone 909 0 #: 1037 C + 1:30 h at 1037 C yellow) + clear at a glance
mineral: production method: medium green 910 2 g + HNO3 10 ml + HCl 15 ml J soaking: 6 d! (yellow tone) separation of liquid and solid f drying
natural # the solid is irradiated with radiation
y to 425.65 Mrad 4. medium green apple 911 2 g + HNO3 25 mi f dipping:, 6 d / separa (yellow-orange tone) liquid and solid formation J natural drying
/ the liquid is irradiated with radiation y to
Mrad 425.65
mineral: 23 production process: a) light green 912 4 g + HNO3 50 ml / from deposit, entry into (orange tone) b) brown boiling / immediately after boiling, light chocolate separation from liquid and solid / rest of 2 # separately for 1 week. I natural drying
/ color dua) liquid b) solid apple green (light 913 the liquid is irradiated with radiation y to your orange) + inten- 424.7 Mrad and dark brown than light orange-green apple
mineral: &num; 11 I production process: apple green (light 914 2 9 + Na2CO3 2 g / 0 # 871 C + 1 h at 871 C / orange) irradiated with y-radiation at 190.22 Mrad
mineral: &num; 15 / production process:
20 g + NaOH 20 g: pale green apple 915 0 # 1065 C (cream beige tone) # a little + accented 916 0 # 1085 C # still a little 917 0 # 1090 C (cream reflection) # still a little 918 0 # 1093 C # again (light 919 0 # 1100 C cream reflection)
mineral: t9 / production process: apple green (tone 920 2 g + Na2CO3 2 gi 0 # 815 C + 15 min to brown) + dark as 815 OC / irradiated y radiation at 64.7 Mrad light apple green (brown tone)
mineral: &num; 27 I production process: dark apple green 921 2 g + Na2CO3 2 g / 0 # 1037 C + 30 min at and in tense (light 1037 C gray tone)
mineral: &num; 11 / production process: green adjoining between 922 2 g + Na2CO3 2 g / 0 # 815 C + '1 h to' 815 C apple green and mint green
mineral: &num; 15 J production process: green between 923 2 g + Na2CO3 2 g 1 Ot 815 oC + 40 min green apple and green 815 C from Paris
mineral: &num; 67 / production process: very yellow green, 924 fine heated powder 0 # 704 C + 4 h at 704 C: very clear 1 g + 5 g pyrex / manual grinding I heated
ge: 5 C per min of 0 # 1245 C + holding pen
1 hour / cooling: 5 C per minute
than the ambient air / all in atmosphere
natural air
minerals: * 5 + * 98 / production process: light yellow green 925 50 g &num; 5 + HCl 200 ml or asbestos r @ HCl splash
# / soaking: 1 5 @ m. / drying on heating plate
# fante: .50 g + .50 g &num; 98 / grinding # green medium yellow 926 irradiated with radiation # to 614.204 Mrad and matte
mineral: 22 / / process of production: a) yellow green 927 4 g + HCl 100 ml / soaking: 4 years / separab) yellow green liquid and solid / drying on c) orange-brown sand bath / color a) liquid b) so-medium medium dried on a sand bath @) dried solid
on hot plate
Minerals: # 18 + # 26 / production process: yellow green 928 .10 g &num; 18 + 1.50 g &num; 26/926 C / 1 hr
# 929 .10 g &num; 18 + 1 g &num; 26/926 C / 1 h evolves # about 930 .10 g &num; 18 + .50 g &num; 26/926 C / 1 h
# 931 .10 g &num; 18 + .25 g &num; 26/926 C / 1 h green blue 932 .10 g &num; 18 + .10 g &num; 26/926 C / 1 h green yellow 933 .25 g & num 18 + 1.50 g, 26/926 C / 1 hr
# becomes 934 .25 g &num; 18 + 1 g &num; 26/926 C / 1 hr adjoining between green 935 .25 g &num; 18 + .50 g &num; 26/926 C / 1 h blue & green yellow # green yellow again 936 .25 g &num; 18 + .25 g &num; 26/926 C / 1 h + green blue # still + green blue 937 .25 g &num; 18 + .10 g &num; 26/926 C / 1 h
Minerals: # 26 + # 29 / production method: green lawn black 938 .10 g &num; 29 + 1.50 g &num; 26/926 C / 1 hr
# 939 .10 g &num; 29 + 1 g &num; 26/926 C / 1 h evolve ver @ 940 .10 g &num; 29 + .50 g &num; 26/926 C / 1 hr
# 941 .10 g &num; 29 + .25 g &num; 26/926 C / 1 h yellow green 942 .10 g &num; 29 + .10 g &num; 26/926 C / 1 h # green tones 943 .25 g &num; 29 + 1.50 g &num; 26/926 C / 1 h varied from 944.25 g &num; 29 + 1 g &num; 26/926 C / 1 hr
# 945 .25 g &num; 29 + .50 g &num; 26/926 C / 1 hr approximating 946.25 g &num; 29 + .25 g &num; 26/926 C / 1 h yellow green 947 .25 g &num; 29 + .10 g &num; 26/926 C / 1 h yellow # 948 1 g &num; 29 + 1.50 g &num; 26/926 C / 1 h # green (yellow tone 949 1 9 &num; 29 + 1 g 26/926 oC / 1 h accented)
mineral: &num; 109 / production method: yellow green 950 3 g + HCl 50 ml / soaking: 2 wk. / drying
on hot plate
mineral: &num; 51 / production process: a) yellow green 951 12 g + HCl 40 ml / soaking: 22 if separation b) dark yellow green of liquid and solid / natural drying /
color of a) solid b) liquid
mineral: # 27 / production method: intense yellow green 952 2 g + Na2CO3 2 g / 0 # 926 C + 1 h at 926 C # + dark 953 X-irradiated at 64.7 Mrad
mineral: &num; 78 / production process: a) light yellow 954 4 g + HNO3 80 ml / soaking: 2 wk. / separates
(light green tone) liquid and solid / drying in a b) bright medium orange dessicator f color of a) solid b) liquid
mineral: &num; 67 / production process: yellow (finely ground 955 finely ground and heated from 0 # 648 C; .50 green) g + HNO3 15 ml / soaking: 2 d / drying over
hotplate
mineral: 77 J production process: yellow green 956 0 # 1037 0C: 1g + H2SO4 50ml J soaking: 2
wk. / drying on a hot plate
mineral: &num; 5 / production method: intense yellow 957 0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
green HCl / soaking: 1 week / drying on
hotplate / radiation irradiated # to
Mrad 190.22
mineral: * 5 J production process: yellow green + dark 958 50 g + HCl 200 ml or asbestos covered with HCl as green yellow / soaking: I wk. drying on hot plate irradiated with radiation at 614.20 Mrad
mineral: &num; 5 / production method: yellow cream a little 959 3 g + HNO3 25 ml / soaking: 3 d / drying + clear as the yellow on hot plate: .50 g + 1 cc light cream ink white printing transparent / grinding my
nuel / 14 overprint, on white paper
glossy i irradiated with radiation y at 22.8 Mrad
mineral: &num; 5 / production method: yellow light cream 960 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on heating plate
fante: .50 g + Na2CO3 .5u g / # 0 # @ 1037 C / ir
written off to electronic radiation at 305,200
rad
minerals: &num; 5 + 16 / production method: light cream yellow 961 50 g &num; 5 + HC1 200 ml or asbestos coated with
HCl / soaking: 1 week I drying on plate
heating: .50 g + .50 g &num; 16 / irradiated at
Radiation # to 614.204 Mrad
mineral: &num; 106 f production process: Naples yellow 962 3 g + 5 g pyrex i manual grinding I heating air: 0 # 926 C + holding for 2 h / the oven
is off I slow cooling in the oven / the
all in natural air atmosphere
mineral: &num; 67 / production process:
Naples yellow 963 powder finely ground and heated to 537 C #
clear # 1 h
yellow of Naples 964 stone coated with paste / 01.704 C / unobstructed
clear I dough / cooled + reheated from 0 # 815 oC
| in the open / picking crystals on
| the stone / their color
Naples yellow 965 paste-coated stone / 871 C i 30 min /
clear I cooled + cleared from the dough + reheated
# 0 # 815 C outdoors / sampling
# crystals on the stone / their color
# finely ground and heated powder:
yellow of Naples 966 0 # 537 C
967 0t.648 oC
mineral: &num; 67 / production process:
Naples yellow 968 1g + 6.50g glass powder (spruce pine clear / old rose batch) / manual grinding i deposit on a plate
/ Milky white ceramic biscuit / heating in a
oven of 0 # 1000 C in normal atmosphere /
slow cooling in the oven
mineral: &num; 67 / production process:
paste-coated stone i 0 # 704 C i cleared
dough i chilled i 0 # 815 oC to the air
free i removal of 'crystals on the
stone: .35 g Naples yellow crystals 969 + HCl 25 ml i natural drying of various tones 970 + HCl 20 ml + NHO3 5 ml / natural drying
971 + HCi 15 ml + NHO3 10 ml / natural drying
972 + HCl 10 ml + NHO3 15 ml / natural drying
# 973 + HCl 5 ml + NHO3 20 ml / natural drying
# 974 + NHO3 25 ml / natural drying
mineral: &num; 67 I production process: yellow kind of 975 finely ground and heated powder 0 # 704 C:
Naples .50 g + NHO3 15 ml / soaking: 2 days / drying
on hot plate
mineral: &num; 67 / production process: Naples yellow 976 finely ground and heated powder of (green tone) 0 # 593 C
mineral: &num; 67 / production process:
finely ground and heated powder å: Naples yellow 977 593 OC / 1 h
(yellow green tone) of Naples 978 648 C / 1 h (green tone a little + accentuated) yellow of Naples 979 704 oC li h (green tone still + accentuated)
Minerals: &num; 67 + &num; 98 / Production Method: Naples Yellow 980 2g + 2g / 704c / 1h (green tone)
mineral: &num; 67 / production process: Naples yellow 981 powder finely ground and heated to 593 C / (accented green tone) 1 h irradiated with X-ray at 64.7 Mrad + darker than Naples yellow (green tone)
mineral: &num; 67 I production process: Naples yellow 982 powder heated to 593 C / 1 h I irradiated with (accented green tone) electronic radiation at 302,831 rad + dark yellow Naples (green tone)
Minerals &# 67 + # 98 I Production Process:
2 g + 2 g I 7Q4 CS 1 h / irradiated to the radius
X to: Naples yellow 983 64.7 Mrad green (orange or pink tone) # Naples yellow 984 424.7 Mrad green + dark [brown] and accented and a little less pink
mineral: &num; 106 / production process: Naples yellow 985 3g + 5g pyrex / manual grinding / fooh (blue gray tone) ge: 5 C per min of 0 # 1245 C + holding pen
1 hour / cooling: 5 OC per minute
that in the ambient air I all in atmosphere
natural air / radiation irradiation #
at 4.94 Mrad
mineral: &num; 5 i production process: very yellow, very 986 5 gt H2SO4 100 ml / soaking: 2 wk. heating / drying on heating plate / irradiated with rayon
Mrad # at 190.22
mineral: &num; 67 I production process: very light yellow 987 0 # 704 C + 4 h at 704 C: 1 9 is sprinkled
on the rounded part of a specimen in
pyrex, heated in the melting state with a
oxyacetylene torch i pigment adheres
and everything is immediately brought back to the state
melting with the torch / cooling
to the ambient air is immediate
mineral: &num; 5 / production method: light yellow 988 0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
green HCl / soaking: 1 week / drying on
hot plate / 37 C / 1 h
mineral: * 5 / production process: light yellow 989 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week f drying on heating plate
.50 g + Na2CO3 .50 g / irradiated with
X-ray at 63.984 Mrad
minerals: &num; 5 + &num; 93 t production process: light yellow 990 50 g &num; 5 + HCl 200 ml or asbestos coated with
HCl i soaking: 1 wk. / drying on plate
heating: .50 g + .50 g &num; 93 / irradiated at
Radiation # to 254.204 Mrad
mineral: &num; 67 / production process: light yellow 991 heated stone from 0 # 760 C + 6 h to 760 C
/ progressive formation of crystals at the
surface of the unmilled mineral / sampling of
crystals / color crystals
Minerals: 5 + 16 / production process: light yellow 992 50 g * 5 + HCl 200 ml or asbestos covered with
HCl / soaking: 1 week / drying on plate
heating: .50 g + .50 g &num; 16 / grinding
minerals: * 5 + &num; 16 f production process: yellow + accented 993 50 g &num; 5 + HCl 200 ml or asbestos coated with
HCl i soaking: 1 wk. / drying on plate
heating: .50 g + .50 9 &num; 16 / irradiated at
electronic radiation at 164,800 rad
mineral: &num; 67 / production process:
finely ground and heated powder of: yellow + accented 994 0 # 704 C as light yellow 4. still + accented 995 0 # 704 C + 4 h at 704 C
mineral: 5 t production process: yellow and orange 996 0 # 537 C: 3 g + HCl 25 ml / soaking: 3 m. / various tones drying on hotplate
997 0 # 593 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
998 0 # 648 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
999 0 # 704 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
1000 0 # 815 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
1001 0 # 871 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
1002 0 # 1037 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
1003 Ot 1093 C: 3 g + HCl 25 ml / soaking: 3 m. f
hot plate drying
1004 0 # 1148 C: 3 g + HCl 25 ml / soaking time: 3 m. i
# hot plate drying
# 1005 0 # 1204 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
# 1006 0 # 1260 C: 3 g + HCl 25 ml / soaking: 3 m. /
hot plate drying
mineral: &num; 50 f production process: yellow; brown J 1007 1 9 is sprinkled on the surface with 15G g of gray paste of glass (sodalime), collected in the state
melting in the furnace (1200 C) on a
metal rod / then, the whole thing is reintroduced
in the furnace and fade to
1200 C f then, the collection is detached from
the metal rod J 0 # 1000 C i cooling
slow in the oven
mineral: 50J production process: yellow 1008 27.4 9 Portland cement + 13cc water J
manual grinding J molding J hardening J die
# pit on the surface of the dried cement of 1 g &num; 50 /
0 # 1037 C yellow / beige 1009 irradiated with radiation # at 18.85 Mrad
mineral: &num; 57 / production method: yellow 1010 stone irradiated with UV laser radiation for
10 shots on a surface of 0.6 cm2 with a
0.210 Joules laser energy having a flux
1.2 x 107 W / cm2 to give energy
2.2 Joules total
mineral: &num; 5 / production method: yellow + dark as 1011 50 9 + MCI 200 mi or asbestos coated with HCl yellow / soaking: 1 wk. / drying on heating plate
fante J irradiated with X-radiation at 140.4 Plrad
mineral: &num; 5 / production method: yellow + clear as 1012 0 # 1037 C: 50 g + HCl 200 ml or asbestos recollects bright yellow green of HCl J soaking: 1 wk. / drying on
hot plate / irradiated with radiation
laser <RTI clear b) orange liquid and solid formulation / drying on medium rust hotplate / color of a) liquid
b) solid
mineral: &num; 106 / production process: light lemon yellow 1016 2 g + 6.50 g glass powder (spruce pine
I brown gray i white batch) / manual grinding I deposit on a milky ceramic biscuit plate / heating in a
oven of 0 # 1000 C in normal atmosphere /
slow cooling in the oven
mineral: &num; 67 / production method: light lemon yellow 1017 paste-coated stone / 871 C / 30 min /
cooling / stone is cleared from the
dough and reheated from 0 # 815 C to air:
.30 g crystals + HCl 25 ml / natural drying
rel i once dried, heating on a
hot plate i color crystals
mineral: &num; 67 / lemon yellow production process 1018 0 # 704 C + 4 h at 704 C: 1 g is sprinkled
on the surface of 150 g of glass paste (soda
lime), which has been collected in the melting state
in the furnace (1200 C) on a rod of
metal / then, the whole thing is reintroduced into the
furnace and flame fired at 1200 OC /
then, the collection is detached from the stem of
metal
mineral: &num; 5 / production process: a) lemon yellow 1019 50 g + HCl 200 ml or asbestos covered with HCl b) bright apple green I soaking: 1 wk. I drying on heating plate
fante: .50 g + Na2CO3 .50 g + HC1 40 mi i
soaking: 5 separation of the liquid and
solid / drying on sand bath / color
a) solid b) liquid
mineral: &num; 107 I production process: medium lemon yellow 1020 6 g + HCl 50 ml / soaking: 2 wk. / drying and bright on hot plate
mineral: * 83 f production process: a) bright lemon yellow 1021 4 g + HNO3 50 ml / soaking: 2 wk. / separab) planting of liquid and solid / natural drying
/ color of a) liquid b) solid
mineral: 5 / production process: bright yellow lemon 1022 50 g + HCl 200 ml or asbestos covered with HC1
/ soaking: 1 week I drying on heating plate
fante J irradiated with radiation W at 102.4 Mrad
mineral: 107 / production process: bright lemon yellow 1023 6 g + HCl 80 ml / soaking: 4 years / drying and powerful on hot plate
mineral: &num; 83 / production process: lemon yellow + 1024 4 g + NHO3 50 ml / soaking: 2 wk. / separaintense and dark liquid and solid / natural drying
the liquid is irradiated with gamma radiation; at
70.4 Mrad
mineral: &num; 82 / production method: egg yolk 1025 4 g + HNO3 20 ml / soaking: 3 d / drying on
hotplate
mineral: &num; 109 / production method: egg yolk 1026 3 g + HCl 50 ml dipping time: 2 wk. / drying (orange reflection) on heating plate / irradiated radiation
&gamma; at 424.7 Mrad
mineral: &num; 37 / production process: a) bright yolk 1027 12 g + HCl 40 ml i soaking: 14 d separation b) bright yellow of liquid and solid / natural drying /
color of a) liquid b) solid
mineral: &num; 5 / production method: bright yellow yolk 1028 or 0 # 1037 C: 50 g + HCl 200 ml i soaking: 1 and bright (sem.tone / warming on heating plate / orange accented) 704 C / 1 h / radiation irradiated &gamma; at
550.22 Mrad
mineral: * 8 J production process: bright yolk 1029 1 g + HCl 50 ml I soaking: 2 wk. / drying
on heating plate / irradiated with radiation
&gamma; at 64.7 Mrad
mineral: 83 J production method: bright egg yolk 1030 0 # 1037 C: 1 g + H2SG4 50 ml / soaking: 2
wk. J drying on heated plate i irradiated
to the electronic radiation at 302,831 rad
mineral: 90 / production method: bright yolk 1031 12 g + HCl 40 ml / natural / irradiated drying
radiation &gamma; at 63.88 Mrad
mineral: &num; 5 J production process: egg yolk + strong 1032 50 g + HCl 200 ml or asbestos covered with HCl and dark as the soaking: 1 wk. Drying on hot-fired egg plate irradiated with radiation at 287.3 Mrad
mineral: 5 / production process: very egg yolk 1033 0 # 1037 C: 50 g + HCl 200 ml or asbestos (green orange tone of HCl / soaking: I sen.J drying on accented) hotplate / 315 CI 1 hr J irradiated at
radiation at 550.22 Mrad
mineral: &num; 27 J production process: egg yolk (very 1034 2 g + Na2CO3 2 g / 0 #: 1037 C + 2 h at 1037 C: slight green reflection) 1 g + 13.7 g Portland cement + 6.50 cc
water / manual grinding I molding / hardening
radiation irradiated at 18.85 Mrad
mineral / number 5 / production process: yellow daisy 1035 50 g + HCl 200 ml or asbestos covered with very bright HCl / soaking: 1 wk. / drying on heating plate
fante J irradiated with X radiation at 360 Mrad
mineral: 77 J production process: yellow sun 1036 0 # 1037 C: 1 g + HCl 80 ml / soaking: 2 wk.

/ drying on a hot plate
mineral: &num; 77 J production process: sun yellow 1037 8 g + HCl 100 ml / soaking: 2 wk. / drying
on a mineral hot plate: &num; 79 I production process: sun yellow + 1038 4 g + HCl 100 ml I soaking: 2 wk. / separafed as the liquid and solid dosage J drying on yellow sun hotplate / radiation irradiated &gamma;
at 64.7 Mrad
mineral: &num; 5 f production process: sun yellow (1039 0 # 1037 C: 50 g + HCl 200 ml or asbestos recoated) green HCl / soaking: 1 wk. J drying on
hot plate J 148 CI 1 h
mineral: &num; 5 i production process: bright yellow sun 1040 0 # 1037 C: 50 g + HCl 200 ml or asbestos green (light green tint) HCl / soaking: 1 wk. / drying on
hotplate
mineral: &num; 72 J production process: golden yellow accented 1041 stone irradiated with X radiation at 360 Mrad
mineral: 24 / production process:
stone irradiated with radiation &gamma; to: golden yellow brunåtre 1042 10 Mrad # old gold (yellow tone 1043 57.4 Irradiated Mrad) #
# old gold (brown tone 1044 148.4 Mrad accented)
mineral: &num; 5 / production method: light yellow ocher 1045 0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
green HCl / soaking: 1 sen. / drying on
hotplate / 315 OC / 1 h / irradiated at
electronic radiation at 162,431 rad
mineral: &num; 48 / production method: light yellow ocher 1046 .20 g + 50 cc high yielding transpaet polyester resin + 1% catalyst / manual grinding i
molding / curing / irradiated with rayon
ment &gamma; at 5.7 Mrad mineral: 15 J production process:
2 g + Na2CO3 2 g: yellow ocher 1047 0 # 704 C + 1 h at 704 C # yellow ocher + dark 1048 0 # 760 C + 1 h at 760 C
minerals: &num; 73 + &num; 76 J production process: yellow ocher + pale 1049 0.14061 g &num; 73 irradiated with radiation y at 2.26 that yellow ocher Mrad + 0.14061 g average radiation irradiated dried pig blood &gamma; at 2.26 Mrad + 0.14061 g &num; 76
/ grinding
mineral: t73 f production process: yellow ocher + pale 1050 0.14061 g &num; 73 irradiated with radiation a at 2.26 that yellow ocher Mrad + 0.14061 g irradiated dried pork blood medium irradiation &gamma; at 2.26 Mrad + Na2CO3
0.28122 g / grinding
mineral: &num; 73 X production process: medium yellow ocher 1051 0.14061 g &num; 73 irradiated with X-radiation at 2.26
Mrad + 0.14061 g irradiated dried port blood
the raoynnement &gamma; 2.26 Mrad / grinding
mineral: &num; 107 i production process: medium yellow ocher 1052 1 g + 5 g pyrex / manual grinding f heating
ge: 5 C per min of 0 # 1245 C + holding pen
1 hour / cooling: 5 OC per minute
only in the ambient air / all in atmosphere
natural air
mineral: &num; 67 J production process: medium yellow ocher 1053 0 # 704 C: .20 g + 50 cc polyes resin
transparent ter + 1% catalyst f grinding
manual / molding / curing / irradiated at
radiation &gamma; at 5.7 Mrad
mineral: &num; 8 f production process: medium yellow ocher 1054 neutron irradiated powder (light green tone) for 2,000 sec at 1022 neutrons I cm2 dry
/ removal of the irradiation beam / recou
green 20 ml photographic developer
D19 from Kodak
mineral: &num; 57 I production process: yellow ocher fairly 1055 stone irradiated with electron radiation at dark (slight reflection 162,431 rad, then at 164,800 rad, then at localized green) 155,082 rad, then neutron radiation
during 300 sec at 1012 neutrons X cm2 / sec
mineral: &num; 5 / production method: yellow ocher (reflection 1056 0 # 1037 C: 50 g + HCl 200 ml or asbestos coated) + pale green HCl / soaking: 1 wk. I drying on dark yellow ocher hotplate: 1g + 0.28122g powder of (green glare) dried pork blood + 0.14061g MgO / grinding
mineral: &num; 83 / production process: orange-yellow ocher 1057 4 g + HNO # 20 ml / soaking: 3 d / drying on clear (green hotplate reflection)
mineral: t67 I production process: yellow ocher beige 1058 finely ground and heated powder 0 # 593 C
50 g + HNOm 15 ml / soaking: 2 days / drying
slow on a hot plate: .20 g + 50 cc
transparent polyester resin + 1% cata
lyser I manual grinding f molding harden
irradiated / irradiated with gamma radiation; at 11.4 Mrad
Minerals: # 50 + # 98 / Production Process: Yellow miei (Reflect 1059 ig + 1g + 5g Pyrex J Manual grinding I Rosé located) Heating: 5 C per min of 0 # 1245 C + Hand
during 1 h I cooling: 5 C by
min to the ambient air / all in atmos
natural air
mineral: 65 production process; medium honey yellow 1060 1 g + 6.50 g glass powder (spruce pine
batch) / manual grinding / deposit on a plate
biscuit ceramic I heating in a furnace
of 0 # 1000 C in normal atmosphere / cooling
slow drying in the oven
mineral: &num; 106 J production process: light bronze yellow 1061 rounded part of a Pyrex test tube
is brought to the state of fusion with a torch
oxyacetylene / then, 5 g &num; 106 is sprinkled
on the molten surface f everything is immediately
is brought back to the state of fusion with the torch
ambient air cooling is immediately
diat i radiation irradiation y at 9.88 Mrad
mineral: &num; 5 J production process: yellow brown + dark 1062 0 # 1037 OC: 50 g + HCl 200 ml or asbestos recouque ie yellow brown green of HCl / soaking: 1 wk. drying on hot plate / radiation irradiation &gamma; at
550.22 Mrad
mineral: production method: light orange yellow 1063 20 g + NaOH 20 gf 0 # 1100 C i irradiated at
radiation there at 2.26 Mrad
mineral: &num; 5 / production method: light orange yellow 1064 0 # 1037 OC: 50 g + HC1 200 ml or asbestos recou
green HCl / soaking: 1 week i drying on
hotplate / 93 C / 1 h
mineral: * 5 / process of production: yellow orange 1065 50 g + HCl 200 ml or asbestos covered with HCl
I soaking: 1 week i drying on heating plate
fante í irradiated with radiation at 254.20 Mrad
mineral: &num; 5 / production method: orange-yellow 1066 3 g + HCl 5 ml + 20 ml water / immediate drying of various tones on a hotplate
1067 3 g + HCl 10 ml + 15 ml water / drying immé
diat on hot plate
1068 3 g + HCl 15 ml + 10 ml water / drying immé
diat on hot plate
1069 3 g + HCl 20 ml + 5 ml water / drying immé
diat on hot plate
# 1070 3 g + HC1 25 ml i immediate drying on a plate
heating
mineral: t5 J production process: yellow orange 1071 3 g + HCl 5 ml + 20 ml water / soaking: 5 days / various tones drying in an oven at 37 ° C
1072 3 9 + HCl 10 ml + 15 ml water / soaking time: 5 days
| / drying in an oven at 37 ° C
| 1073 3 g + HC1 15 ml + 10 ml water I soak: 5 days
Drying in an oven at 37 ° C
1074 3 g + HCi 20 ml + 5 ml water / soaking: 5 days
J drying in an oven at 37 oC
# 1075 3 g + HCl 25 ml / soaking: 5 days / drying in
an oven at 37 C
mineral: production method: yellow orange 1076 0 # 815 C: 3 g + HNO3 5 ml + HCl 20 ml / trem
page: 3 days / hot plate drying
mineral: production method: yellow orange 1077 Ot 648 C: 3 g + HCl 25 ml i soaking: 3 ji of various tones drying on a hotplate
1078 0 # 704 C: 3 g + HCl 25 ml / soaking time: 3 d /
hot plate drying
1079 0 # 760 C: 3 g + HCl 25 ml / soaking time: 3 d /
hot plate drying
1080 0 # 815 C: 3 g + HCl 25 ml / soaking time: 3 d /
hot plate drying
mineral: &num; 5 / production method: bright orange yellow 1081 3 g + HCl 20 ml / soaking: 24 hrs J drying on
hotplate
mineral: &num; 5 J production process: bright orange yellow 1082 3 g + HCl 25 ml / immediate drying on plate
heating
mineral: * 5 / production process: bright orange yellow 1083 50 g + HCl 100 ml / soaking: 5 m. / drying
on hot plate
mineral: t5 J production process: bright orange yellow 1084 0 # 1037 C: 50 g + HCl 200 mi or asbestos recou
green HCl i soaking: 1 wk. / drying on
hot plate I 704 CJ 1 h I irradiated at
electronic radiation at 164,800 rad
Minerals: # 50 + # 98 / Production Process: bright orange yellow 1085 .30 g + .30 g + Na2CO3 .30 g / deposit on one
window measuring i "x 1" x 1/8 "X 0 # 982 C /
slow cooling in the oven
Mineral: 90 / Protected Production: Very Orange Yellow 1086 12g + HCl 40ml / Bright Natural Drying
mineral: &num; 50 / production method: light orange yellow 1087 1 g powder deposited on a glass measuring (green reflection i "x 1" x 1/8 "D 0 # 982 oC i localized cooling) slow baking
mineral: &num; 67 i production process: joint between yellow 1088 'stone coated with paste i 871 C / 30 min i from Naples clear and cooling i cleared from the paste and reorange clear heated in the open air Ol 815 C / prelve -
crystals on the surface of the stone:
.30 g crystals + HNO3 25 ml / drying
natural i once dried, heating on
a hot plate J color crystals
mineral: &num; 50 / production method: medium yellow orange 1089 1 g powder deposited on a glass measuring and bright (green reflection 1 "x 1" x 118 i 0 # 871 @ CJ localized cooling) slow baking # orange yellow still 1090 1 g powder deposited on a glass measuring + bright (green reflection 1 "x 1 x 1/8" I 0 # 926 C i localized cooling) slow in the oven
minerals: &num; 50 + &num; 98 / production method: bright yellow orange 1091 .45 g + .45 gi deposit on a glass measuring
1 "x 1" x 1/8 "/ 0 # 926 C / Cooling
slow baking # orange yellow + 1092 .45 g + .45 g / deposit on a glass measuring bright (green reflection 1 "x 1" x 1/8 "/ 0 # 982 C / localized cooling) slow baking
mineral: 17 production process: bright yellow orange 1093 1 g + 5 g pyrex i manual grinding J heating / dark iron gray ge: 5 C per min of 0 # 1245 C + holding pen
1 hour / cooling: 5 C per minute
only in the ambient air / all in atmosphere
of natural air -I + accented and vivid 1094 irradiated with radiation y to 9.98 Mrad
Minerals: # 50 + # 98 / production method: medium orange 1095 .30 g + .30 g + Na2COz .30 gy deposit on one (green glass reflection measuring 1 "x 1" x 118 i 0 # 926 C / located) slow cooling in the oven
mineral: &num; 105 i production process: pale orange 1096 stone irradiated with UV laser radiation during
0.5 min over a surface of 0.16 cm2 with a
0.180 Joule laser energy having a flux of
1.8 x 107 W / cm2 to give an energy
total of 54 Joules
mineral: &num; 5 I production method: light orange 1097 5 g + H2SO4 100 ml / soaking: 2 sen. I drying
hot plate J 704 CJ 1 h
mineral: &num; 5 / production process: a) light orange 1098 50 g + HCl 200 ml or asbestos covered with HCl b) orange-beige J soaking: 1 wk. / drying on heating plate
: 50 g + Na 2 CO 3 .50 g + HNO 3 40 ml
soaking: 5 days / separation of liquid and
solid 1 drying on sand bath / color
a) liquid b) solid
mineral: 5 production process: light orange 1099 0 # 1037 OC: 50 g + HCl 200 ml or asbestos recou
green HCl / soaking: 1 week f drying on
# heating plate / 537 C / 1 h
Drange pronounced 1100 0 # 1037 C: 50 g + HCl 200 ml or asbestos retouch
green HCl / soaking: 1 week, I drying on
# hot plate / 704 C / 1 h #
Drange pronounced 1101 0 # 1037 C: 50 g + HCl 200 ml or asbestos retouched
green HCl i soaking: 1 wk. / drying on
hot plate / 760 C / 1 h
Drange pronounced 1102 0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
green HCl J soaking: 1 wk. / drying on
hotplate i 815 C i 1 h # orange + clear 1103 Ot1037 OC: 50 g + HCl 200 ml or asbestos recou
green of HC1 J soaking: 1 wk. J drying on
hot plate J 871 C i 1 h
minerals: &num; 5 + &num; 98 / production method: light orange 1104 5 g &num; 5 + H2SO4 100 ml / soaking: 2 wk. f
hot plate drying: 2 g + 2 g &num; 98 f
704 C / 1 h
mineral: 15 I production process:
Drange + intense 1105 0 # 815 C: 3 g + HCl 15 ml + HNO3 10 ml / and dark soaking: 3 days / drying on hotplate:
.30 g + 50 cc transpa polyester resin
rent t 1% catalyst / manual grinding í
casting I curing / irradiated with rayon
electronically at 305,082 rad
mineral: &num; 15 / production process:
2 g + Na2CO3 2 g: light orange 1106 0 # 815 C + 1 hr at 815 C # + dark and accented 1107 0 # 871 C + 1 hr at 871 C # still + 1108 0 # 926 C + 1 h at 926 C # and emcpre + 1109 0 # 982 C + 1 h to 982 C # and still 1110 0 # 1037 C + 1 h to 1037 C
mineral: &num; 5 / production process: orange 1111 5 g + HNO3 80 ml f soaking: 2 wk. i drying
heating plate i 704 CI 1 h
mineral: &num; 5! production process:
irradiated stone with radiation y å: light orange 1112 102.4 Mrad
#
+ dark and accented 113 287.3 Mrad
mineral: &num; 5 S production process: tonal orange 1114 0 # 537 C: 3 g + HCl 25 mi i immediate drying varied @ on hotplate
1115 0 # 648 C: 3 g + HC1 25 mi i immediate drying
# on heating pad #
# 1116 0 # 871 C: 3 g + HCl 25 ml / immediate drying
# on hot plate #
# 1117 0 # 1037 C: 3 g + HCl 25 ml / immediate drying
# on hot plate #
# 1118 0 # 1260 C: 3g + HCl 25ml / immediate exchange
on hot plate
mineral: &num; 50 J production process: orange / yellow / 1119 1 g powder + 27.4 g Portland cement + 13 dark green f gray cc water i manual grinding 1 molding J harden brown I orange / 3 g powder on the cement
# 926 C
Minerals: 50 + 100 / production process:
4 g powder &# 50 deposited on a stone * 100: orange @ 1120 760 C i 1 h
1121 815 C i 1 h
1122 871 C i 1 h orange / brown 1123 0 # 926 C
# 1124 0 982 C
# 1125 0 # 1037 C
mineral: &num; 57 / production process: orange 1126 stone irradiated with UV laser radiation
10 min on a surface of 0.6 cm2 with
a 0.195 Joule laser energy having a flux
of 1.1 # 107 W / cm2 to give an energy
total of 2,340 Joules
mineral: &num; 105 I production process: orange 1127 stone irradiated with laser radiation UV pen
10 min on a surface of 0.16 cm2 with
a laser energy of 0.130 Joule having a flux
of 6.5 # 106 W / cm2 to give an energy
total of 54 Joules
mineral: 5, process of production.

 0 # 871 C: 3 g + HCl 25 ml / soaking: 3 m.

/ drying on a hot plate: .30 g + 50 cc
transparent polyester resin + 1%
catalyst I manual grinding / hard molding
c irradiated irradiation at: orange 1128 5.7 Mrad # + bright and dark 1129 34.2 Mrad
mineral: &num; 5 J production process: orange + pale as 1130 0 # 1037 OC: 50 g + HCl 200 ml or asbestos recoul'orange green medium of HC1 J soaking: 1 wk. J drying on
hotplate / 815 CJI hi irradiated at
electronic radiation at 302,831 rad
mineral: 215 f production process: medium orange 1131 0 # 815 OC: 3 g + HCl 15 mi + HNO3 10 mi i
Soaking: 3 days drying on a plate
hot plate I formation of 2 layers of
superimposed colors J the surface layer:
537 C / 1 h
Minerals: # 6 + # 98 / Produttion Process: orange rust 1139 250 g &num; 6 + HCl 1650 ml in a clear 2000 ml beaker or asbestos covered with HCl in a con
standing height J soaking: 1 wk drying
on heating plate J formation of 2 layers
of superimposed colors / the layer in
weight: 2 g + 2 g &num; 98 1 815 C i 1 h mineral: &num; 5 J production process: orange rust 1140 3 g + HNO3 25 ml / soaking: 3 d / drying various heating plate intensities
# 1141 3 g + HNO3 20 ml + HCl 5 ml / soaking time: 3 d
hot plate drying #
# 1142 3 g + HNO3 15 ml + HCl 10 ml / tempering: 3 d /
drying on heating plate #
# 1143 3 g + HNO3 10 ml + HCl 15 ml / soaking time: 3 d
# hot plate drying #
# 1144 3 g + HNO3 5 ml + HCl 20 ml / soaking time: 3 d /
hot plate drying
mineral: &num; 6 / production method: orange rust 1145 2 g + Na2CO3 2 g / 760 OC í 1 h / irradiated at
electronic radiation at 162, 431 rad
mineral: &num; 15 / production method: orange rust + 1146 2 g + Na2CO3 2 g / 0 # 815 C + 55 min at intense and dark 815 C / irradiated at y radiation at 64.7 Mrad
Minerals: &num; 6 + &num; 98 / Production Method:
6 250 g + HCl 1650 ml in a beaker of 2000
ml or asbestos covered with HCl in a tale
at height f soaking: 1 wk. 1 drying
on heating plate I 2-layer formation
of superimposed colors, the layer
surface: orange rust + 1147 2 g + 24 g &num; 98 t 704 CI 1 h ciair orange rust dark # orange rust 1148 2 g + 2 g &num; 98/704 c / 1 h dark
mineral: &num; 6 I production method: orange rust 1149 250 g + HCl 1650 ml in a 2000 ml dark beaker or asbestos covered with HCl in a container
in height J soaking: 1 wk. / drying on
hot plate I formation of 2 layers of
superimposed colors / the cost in
depth: 704 C.! 1 h
mineral: &num; 6 / production method: orange rust 1150 250 g + HCl 1650 ml in a dark 2000 ml béche or asbestos covered with HCI in a container
in height I soaking: 1 wk. J drying on
hot plate I formation of 2 layers of
superimposed colors I the layer in
surface area: 704 C / 1 h
mineral: &num; 5 J production process: orange rust I 1151 50 g + HCl 200 ml or asbestos covered with HCl green turquoise J soaking: 1 wk. I drying on plate heaters pale gray iton) fante: ig + Na2CO3 3 g / 0 # 815 C
mineral: 5 t production process: orange rust bright 1152 50 g + HCl 200 ml or asbestos covered with HCl i light gray soaking 1 week. I drying on turquoise chaufvert plate) fante: 2 g + Na2CO3 4 g Ot 815 C
mineral: &num; 15 / production method: orange rust 1153 0 # 815 C: 3 g + HNO3 20 ml + HCl 5 ml / tremci air (pinkish tone) page: 3 i drying on a hotplate I
irradiated with electronic radiation at 302,831
rad
Mineral: 15 ° C production process: orange rust 1154 0 # 815 C: 3 g + HNO3 20 ml + HCl 5 ml / tremmoyen and enough page: 3 i drying on hot plate bright (pinkish tone) orange rust 1155 Ot 815 C: 3 g + HNO3 15 ml + HCl 10 mi i + clear (pinkish tone) soaking: 3 d J drying on hotplate orange rust 1156 0 # 815 C: 3 g + HNO3 10 ml + HCl 15 ml f + clear (your rosé) soaking: 3 0 / drying on a hotplate
mineral: &num; 15 / production method: organ rust (tone 1157 0 # 815 C: 3 g + HNO3 20 ml + HCl 5 ml / tremors) + dark than page: 3 d / drying on hot plate / orange rust irradiated with radiation # at 64.7 Mrad average (pink tone)
mineral: &num; 6 / production method: orange rust 1153 2 g + Na2CO3 2 g / 0 # 648 C = h at 648 C (red tone) J irradiated with radiation W at 550.22 Mrad
mineral: &num; 6 / production method: orange rust 1159 250 g + HCl 1650 ml in a beaker of 2000 ml dark (red tone) or asbestos covered with HC1 in a container
in height and soaking: 1 wk. 1 drying on
hot plate J formation of 2 layers of
superimposed colors J the layer in
depth: 815 oC / 1 h
minerals: &num; 6 + &num; 98 I production process; orange medium brick 1160 2 g + 2 g / 704 C / 1 h
minerals: &num; 6 + &num; 98 / production method: orange medium brick 1161 2 g + 2 g / 704 C / 1 h / irradiated at the radius (brown tone) # at 550.22 Mrad
mineral: &num; 5 / production method: burnt orange 1162 2 g powder + HCl 20 ml i soaking: 2 wk. / (brown tone) irradiated with radiation y at 5.7 Mrad / drying
on sand bath
mineral: &num; 5 / production method: burnt orange 1163 stone covered with HC1 20 mi / soaking:
wk. / radiation irradiated at 5.7 Mrad /
drying on a sand bath
mineral: &num; 57 / productIon process: medium burnt orange 1164 irradiated powder with strong neutron radiation for 2,000 sec at 1012 neutrons I cm2 I dry:
2 g coated with 20 ml developer D19 of
Kodak
mineral: &num; 67 i production process: bright burnt prange 1165 0 # 704 C + 4 h at 704 C: 1 g is sprinkled
on the rounded part of a specimen in
pyrex, heated to a state of fusion with a
pxyacetylene torch J the pigment adheres to it
and everything is immediately brought back to the state
melting with the torch / cooling
to ambient air is immediate / irradiation at
radiation at 9.88 Mrad
Minerals: 77 + 5 Production Process: Burnt prange + 1166 2g + 27g + Na2CO3 2g / 0 # 1037 C + 1:30 h to pale as the orange 1037 C. * 5 is heated 0 # 1037 OC: 50g + dark burned HCl 200ml or asbestos covered with HCl / soaking:
t week drying on a hot plate. 1 g
of the 2 results obtained + 0.14061 g Mg0 /
grinding
Minerals: &num; 27 + 5 production process: burnt orange + 1167 2 g &num; 27 + Na2CO3 2 g J 0 &num; 1037 oC + 1:30 h to påle than orange 1037 C. &num; 5 heated 0 # 1037 C: 50g + dark burned HCl 200 mi or asbestos covered with HC1 / soaking:
1 week J hot plate drying. 1 g
of the 2 results obtained + K2CO3 0.28122 g /
grinding
Minerals: # 27 + # 5 / Production Process: dark burnt orange 1168 2g &num; 27 + Na2CO3 2g / 0 # 1037 C + 1:30 h to
1037 C. 5 is heated 0 # 1037 C: 50 g + HCl
200 ml or asbestos covered with HCl i dipping:
1 week I drying on a hot plate. 1 g
2 results obtained i grinding
Minerals: # 34 / Production Process: Burnt orange 1169 1g + 5g pyrex / manual grinding / yellow chaufiton) fage: 5 C per min of 0 # 1245 OC + hold
Fending 1 hi cooling: 5 C per min
to the ambient air / all in atmosphere
natural air
mineral: &num; 57 f production process: caramel orange 1170 5 g stones + 13.74 g Portland cement +
6.50 cc water I manual mixing / molding /
hardening ft 315 C / cooling I
Radiation irradiation # at 18.85 Mrad J
# color stones # orange caramel 1171 5 g stones + 13.74 g Portland cement + [one tone 6.50 cc water i manual mixing / molding i different) hardening J 0 # 704 oC J cooling J
X-ray irradiation at 18.85 Mrad I
color of stones
mineral: * 50 i production process: orange caramel 1172 1 g + Na2CO3 1 g / crushed and spread over
(your red tone)
mineral: &num; 50 / production method: caramel orange 1173 rounded part of a pyrex test tube
(green reflection) is heated with an oxyacetylene I torch
then, 5 g of galena is sprinkled on the
molten face i galena adheres to it and all
is immediately returned to the state of fusion
with the torch / air cooling
ambient is immediate
mineral: &num; 57 / production process: medium orange 1174 stone irradiated with bright electronic radiation (very light tone 162,431 rad, then 164,800 rad, then amber) 155,082 rad, then for 4 hours X-ray
using a therapeutic device, compor
448 shots every 30 sec
the during 1/10 of dry to 100 milliamper and iO
kV at a distance of 40 inches, then to the radius
electronically at 140,400 rad
mineral: &num; 50 i production process: medium orange ocher 1175 1 g powder deposited on a window measuring
1 "x 1" x 1/8 "/ 0 # 787 C / Cooling
slow in the oven
mineral: &num; 5 I production process: orange (light ton 1176 0 # 1037 C: 50 g + HCl 200 ml or ashes recouchamois) green HCl / soaking: 1 wk. / drying on
hot plate / 926 C / 1 h
mineral: &num; 67 / production process:
paste-coated stone / 871 CJ 30 min /
cooling / stone is cleared from the
dough and reheated from 0 # 815 C to the open air
/ formation of crystals on the stone: .30 g
crystals: light beige orange 1177 + HNO3 20 ml + HCl 5 ml / natural drying /
once dry, heating on a plate
warming / color crystals a little + accented 1178 + HNOu 15 ml + HCl 10 mi / natural drying I
once dry, heating on a plate
# heating / crystal color # orange beige + påle 1179 + HNO3 10 ml + HCl 15 ml / natural drying /
once dry, heating on a plate
# heating / color crystals still + pale 1180 + HNOx 5 ml + HCl 20 ml I natural drying /
once dry, heating on a plate
heating / color crystals
mineral: t5 J production process: light beige orange 1181 50 g + HCl 200 ml or asbestos covered with HCl and vivid i J soaking: 1 wk. / drying on hot plate
fante: .50 g + Na2CO2 .50 g / grinding
at orange beig a 1182 irradiated with electronic radiation at 164,800 little + accented rad
mineral: * 15 J production process: beige prange 1183 2 g + Na2CO3 2 g / 0 # 815 C + 20 min to
815 C
mineral: &num; 67 / production process: orange beige 1184 finely ground and heated powder of 0 # 648 OC: .50 9 + HNO3 15 ml J soaking: 2
J Drying on a hot plate: .20 gt 50
cc transparent polyester resin + 1%
catalyst / manual grinding / J hard molding
curing / irradiated with radiation # to 5.7
mrad
mineral: &num; 5 / production method: medium beige orange 1185 0't1148 C / X-irradiated at 614.20
mrad
minerals: &num; 5 + &num; 98 J production process: orange brown + pale 1186 5 g &num; 5 + H2SG4 100 ml / soaking: 2 sen. brown brown orange drying on hot plate: 2 g + 2 g &num; 98 / clear 704 C / 1 h / irradiated with elec
tronic at 302,831 rad
minerals: &num; 5 + t98 J production process: light brown orange 1187 5 g &num; 5 + H2SC4 100 ml I soaking: 2 wk. 1
hot plate drying: 2 g + 2 g &num; 98 J
704 CJ 1 h
mineral: &num; 5 / production method: light brown orange 1188 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on heating plate
fante: 3 g + Na2CO3 1 g / 0 # 926 C
mineral: 5 # production process: orange brown + dark 1189 3 g + HC1 25 ml J soaking: 5 d / drying in
an oven at 37 C: .50 g + I cc ink. Sun-
white transparent primerie / manual grinding /
1 print on glossy white J paper irradiated
at the radiation y to 22.8 Mrad
minerals: &num; 50 + &num; 98 / production method: orange brown 1190 1g + 1g + 6.50g glass powder (spruce
plne batch) ./. Manual crushing / deposit on a
ceramic biscuit plate / heating in
an oven of 0 # 1000 C in a normal atmosphere /
slow cooling in the oven / irradiation
radiation at 9.88 Mrad
mineral: * 5 t production process: brown orange 1191 50 g + HCl 200 ml or asbestos covered with HCi
/ soaking: 1 week / drying on heating plate
fante: 3 g + Na2CO3 4 g / 982 C / 15 min
mineral: &num; 15 / production method: brown prange 1192 0 # 1054 C: 3 g + HCl 25 ml / soaking: 3 d /
hot plate drying
mineral: &num; 57 / production method: orange brown 1193 stone irradiated with electronic radiation at
162,431 rad and then to X-ray using
a therapeutic device for 4 hours, con
carrying 448 shots every 30 sec
valle during 1/10 of sec to 100 milliamper at
70 kV at a distance of 40 inches, then at
electronic radiation at 140,400 rad
mineral: * 5 I production process: medium brown orange 1994 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on heating plate
fante: 3 g + Na2CO3 1 g / 0 # 982 C
minerals: &num; 98 + production method: medium brown orange 1195 5 g &num; 5 + HNO3 80 ml / soaking: 2 wk. !
hot plate drying: 2 g + 2 g &num; 98
/ 704 C / 1 h
minerals: * 50 + # 98 / production method: medium brown orange 1196 .45 g + .45 g J despite t on a glass measuring
1 "x 1" x 1/8 "/ 0 # 871 C
mineral: &num; 5 / production process: orange a little + 1197 0 # 1037 OC: 50 g + MCl 200 mi or green recoated asbestos of HCl / soaking: 1 wk. f drying on
heating plate J 815 C / 1 h / irradiated with
radiation at 550.22 Mrad
Minerals: # 5 + # 98 / production method: orange brown + pale 1198 &num; 5 0 # 1037 C: 50g + HCl 200ml or asbestos reque the dark orange covered with HCl I soaking: 1 wk. / drying on
hot plate: 2 g + 2 g &num; 98/815 OC J 1
h / irradiated with electronic radiation at
302,831 rad
mineral: 5, production process:
50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on hot plate
f ante: dark brown orange 1199 3 g + Na2CO3 igf 0 # 1037 OC
# 1200 3 g + Na2CO3 1 g / 0 # 1093 C
# 1201 3 g + Na2CO3 4 g / 982 C / 30 min
mineral: production method: salmon orange 1202 2 g + Na2CO3 2 g / 815 ° C + 10 min at 815 ° C
Minerals: # 5 + # 98 / production method: salmon orange 1203 5g &num; 5 + H2SO4 100ml i soaking: 2 wk. / dark drying on hot plate: 2 g + 2 g &num; 98 i
704 C / 1 h / irradiated with radiation # to
Mrad 190.22
Minerals: # 50 + # 87 / production method: light pink orange 1204 27.4 g Portland cement + 13 cc water + 5 g / orange yellow / 87 mass Portland cement f light orange pink manual grinding / molding / hardening /
addition to the surface of the dried cement of 3 g t50
/ 0 # 926C
mineral: 5, production process:
50 gt MCl 200 ml or asbestos covered with HC-1
J soaking: 1 wk I drying on heating plate
Fante:
- 3 9 + Na2CO3 2 g: light pink organge 1205 0 # 648 C # orange pink + dark 1206 9 # 704 C and brown # # organge rosé - dark 1207 0 # 760 C and + accented # - 3 g + Na2CO3 4 g : light pink orange 1208 0 # 648 C # orange pink + dark 1209 0 # 704 C and accented # orange (light tone 1210 0 # 760 C pink) + + dark and accented
mineral: &num; 5 / production process: orange rosé + clair 1211 3 g + HNO3 5 ml + HC1 20 ml f soaking: 3 d J orange rosé drying on hotplate I irradiated with
X radiation at 190.22 Mrad
mineral: &num; 6 f production process: orange red + 1212 2 g + Na2CO3 2 g / 0 # 648 C + 1 ha 648 C bright and vivid as / irradiated with radiation y at 190.22 Mrad medium orange red
mineral: &num; 64 / production process: bright red orange 1213 1 g + 5 g pyrex / manual grinding / with green moiré heating: 5 oC per min of 0 # 1245 C + holding apple I for 1 h I cooling: 5 C min
up to the ambient air I all in atmosphere
of natural air a little + accented 1214 irradiated with radiation g at 9.88 Mrad and dark
mineral: &num; 22 I production process: bright red orange 1215 1 g + 5 g pyrex f manual grinding i heated with green moiré fage: 5 C per min of 0 # 1245 C + holding chocolate brown apple i during 1 hr cooling : 5 C per very dark min to ambient air / all in atmosphere
d @ natural mineral air: # 5 f production process:
50 g + HCl 200 ml or asbestos covered with HCl
I soaking: 1 week / drying on hot plate
Fante:
- 2 g + Na2CO3 4 g: bright red orange / 1216 0 # 871 C very light turquoise green #
# - 2 g + Na2CO3 3 g: bright red orange i 1217 0t815 C light gray orange bright red / 1218 0 # 871 C light turquoise green
# - 4 g + Na2CO3 4 g: orange red påle 1219 0 # 648 C (very light purple tone)
# orange red + 1220 p # 704 C accented (light to purple)
mineral: * 57 / production process: pink orange 1221 6 g stones + 13.74 g Portland cement +
6.50 cc water f manual kneading f molding
hardening / 0 # 1037 C / irradiation at
Radiation # at 18.85 Mrad
mineral: &num; 15 / production process:
2 g + Na2CO3 2 g: salmon 1222 0 # 537 C + 1 h at 537 ° C.
# salmon 1223 0 # 648 C + 1 h to 648 C
mineral: production method: salmon 1224 0 # 537 C: 3 g + HNO3 25 ml / soaking: 3 days
i drying on a hotplate
mineral: * 15 i production process: medium salmon 1225 871 OC I 1 h
mineral: 5, production process:
5 g + HNOx 80 @ ml I soaking: 2 wk. / drying
on plate. heating / irradiated with radiation # to: medium salmon, int 1226 190.22 Mrad tense and bright # pink salmon orange 1227 550.22 Mrad medium
Minerals: &num; 15 + &num; 68 / production method: pronounced salmon 1228 1 g + 1 g / 982 C / 45 min
mineral: &num; 15 / production method: dark salmon 1229 0 # 926 C: 3 g + HCl 25 ml / soaking: 3 d /
hot plate drying
mineral: &num; 15 / production method: salmon (brown ton) 1230 irradiated with y-radiation at 287.3 Mrad
mineral: 15 / production method: dark salmon (1231 0 # 815 OC, 3 g + HNO3 20 ml + HCl 5 ml / trembrun) page: 3 d / drying on a hotplate /
irradiated with radiation # at 424.7 Mrad
mineral: 95 I production process: a) bright pink (light 1232 0 # 1037 C: .30 g + H3PO4 100 mi i soaking: 4 ton purple) b) white aged / drying on hotplate / color
a) liquid b) solid
mineral: &num; 95 I production process: a) pink violet 1233 3 g + HNOs 80 ml / soaking: 2 wk. / separamoyen I medium red, liquid and solid i drying on luminous b) pink hotplate / color of a) liquid
# b) solid #
# the liquid is irradiated with gamma radiation to: purple pink and 1234 64.7 Mrad red bright + pale than the monyen
purple pink (tone 1235 424.7 Mrad brown) and brown + dark brown
minerals: &num; 5 + &num; 98 / production process:
&num; 5 0 # 1037 C: 50 g + HCl 200 ml or asbestos
covered with HCl / soaking: 1 wk. i drying
on a hot plate: 1 g + Na2CO3 2 g +
&num; 98 1 g: pearly pink, at 1236 0 # 815 C intense pearly pink metallic sheen, 1237 0 # 871 C with metallic luster
with pearly pink + dark, 1238 0 # 926 C with metallic luster
Minerals: &num; 5 + &num; 98 @ Production method: Pearl pink, with luster 1239 1 g '+ Na2CO3 2 g + ig / 01926 metallic C [other than [i-high]
minerals: &num; 5 + &num; 98 / production process:
&num; 5 0 # 1037 C: 50 g + HCl 200 ml or asbestos
covered with HCl / soaking: 1 wk. / drying
hotplate: pearly pink i240 1 g + 1 g &num; 98 i 0 # 926 C pearly pink (tone 1241 1 g + Na2CO3 2 g + 1 g &num; 98/0 # 982 C brown), metallic luster
# + accented 1242 1 g + Na2CO3 2 g + 1 g &num; 98/0 # 1037 C
mineral: &num; 89 i production process: very pink, very 1243 two independent masses of 150 g of clear glass paste (sodalime) each are collected at
l @ state of fusion in the furnace (1200 C)
on 2 independent metal rods i 2 g of
selenium is sprinkled on the surface of a single
the face of one of the collections, which is found
by the other collection i then, the 2 surfaces
trap selenium between the two collections
of glass / everything is reintroduced into the
furnace and remelted at 1200 OC / and then the
resulting collection is detached from the stems
Minerals: # 15 + # 80 / production process: pink + påle as 1244 .50 g + .50 g / 0 # 1037 C / irradiated with radiation # at 64.7 Mrad
mineral: &num; 95 / production process: a) light pink 1245 3 g + H2SO4 80 ml I soaking: 2 wk. / separab) pink t tting liquid and solid f drying on
hot plate / color of a) solid
b) liquid
mineral: # 95 / production method: pink I brown 1246 3 g + 20 ml KCN solution (95% water
distilled + 5% KCN) / natural drying
mineral: &num; 15 / production process:
0 # 815 C: buff pink + påle 1247 - irradiated with rayane # to 64.7 Mrad than pale buff pink
to buffy pink + 1248 - irradiated with electronic radiation to tense and dark than 302,831 rad pink buff clear
mineral: &num; 103 / production method: old medium rose 1249 4 g + H2S04 20 mi i soaking: 24 h 1 drying
on hot plate # + accented and dark 1250 irradiated with radiation # at 64.7 Mrad
mineral: * 103 I production process: a) old pale pink 1251 4 g + HNO3 20 ml J soaking: 24 h / separation (light orange tone of liquid and solid í drying on plate b) wine red wine heating I color solid ai b) liquid
Mineral: 5 J production process:
50 g + HCl 200 ml or asbestos covered with HC1
J soaking: i wk. / drying on heating plate
f ante:
- 4 g + Na2CO3 4 g: old rose (tone 1252 0 # 537 C beige and light purple reflection) old rose (tone 1253 0 # 593 C orange pink and light violet reflection # old pink (tone 1254 - 4 g + Na2CO3 2 g / 0 # 593 C orange pinkish beige and purple reflection)
mineral: &num; 43 J production process: old rose (tone 1255 1g + 1cc brown white synthetic enamel paint) transparent for auto J grinding manual / ap
on a piece of body sheet
measuring the x 1 "/ irradiated to radiation # to
57.4 Mrad
mineral: &num; 5 f production process:
50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on heating plate
Fante:
-4 g + Na2CO3 3 g: old rose (tone 1256 0 # 537 C gray and pinkish orange reflection) # + accented 1257 0 # 593 C # old rose (tone 1258 - 4 g + Na2CO3 2 g / 0 # 537 C gray and purple reflection) old medium pink 1259 - 4 g + Na2CO3 1 g! 0 # 648 C
(your gray and reflection
orange)
mineral: &num; 95 J production process: very intense pink 1260 0 # 1037 C: .30 g + H2S04 50ml / soaking:
(your red tone) sem. / drying on heating plate # much + accented 1261 irradiated with X radiation at 64.7 Mrad
mineral: &num; 6 / production method: burgundy rose 1262 250 g + HCl 1650 ml in a beaker of 2000 ml (brown tone) or asbestos covered with HC in a container
in height / soaking: 1 wk. I drying on
hotplate / formation of 2 layers of
superimposed colors / that of surface:
815 CII h
mineral: &num; 6 / production process: red wine lees 1263 0 # 1093 C / irradiated with radiation # at 555.92 (brown tone) pronounced Mrad
mineral: * 10 i production process: orange red 1264 2 g + HCl 20 ml / soaking: 3 d / drying on
hotplate
mineral: &num; 58 i production process:
10 g + 10 g NaCl: bright orange red 1265 0 # 537 C # + dark 1266 0 # 704 C
mineral: &num; 6 / production process:
250 g + HC1 1650 mi in a beaker of 2000 ml
or asbestos covered with HCl in a container
in height / soaking: 1 wk. i drying on
hotplate; formation of 2 layers of
superimposed colors:
- deep layer: red burgundy 1267 871 OC / 1 h clear #
# + accented 1268 926 C / 1 h red kind 1269 - the surface layer: 926 C / 1 h burgundy
mineral: &num; 6 I production process: burgundy red 1270 0 # 1037 C: 50 g + HCl 200 ml or green reclaimed asbestos of HCl / soaking: 1 wk. / drying on
hotplate
mineral: * 6 S production process: burgundy red 1271 0? 1037 C: 50 g + HCl 200 ml or asbestos rewashed tending towards green HCl I soaking: 1 wk. / drying ie red brown) immediately on hot plate
mineral: &num; 6 / production process: red burgundy + 1272 0 # 1037 C / irradiated with radiation # to intense and dark as 550.22 Mrad dark burgundy red
mineral: 6 t production process: burgundy red + 1273 0 # 1037 C: 50 g + HCl 200 ml or asbestos covered] and brown green HCl / soaking: 1 wk. drying on burgundy red hotplate / irradiated with dark radiation at 550.22 Mrad
mineral: 96 I production process: burgundy red + 1274 0 # 1037 C: 50 g + HC1 200 ml or asbestos covered and brown green HCl / immediate drying on the plate heating red burgundy / irradiated with X to dark radiation @tending another 550.22 Mrad to the brown red]
mineral: &num; 6 i production method: dark brown red 1275 250 g + HCl 1650 ml in a 2000 ml beaker
or asbestos covered with HCl in a container
in height / soaking: 1 wk. / drying on
hotplate / formation of 2 layers of
superimposed colors i the surface one is
| heated at 815 oC f 1 h # a little + clear 1276 irradiated with electronic radiation at 162,431
rad
mineral: &num; 81 i production process: dark brown red 1277 1 g + 5 g pyrex f manual grinding / heat (purpurin ton) fage: 5 C per min of 0 # 1245 C + holding
during 1 hr cooling: 5 C per min
up to the ambient air f all in atmosphere
of natural air # + dark 1278 irradiated with radiation # at 9.88 Mrad
mineral: &num; 6 / production method: red (light tone 1279 250 g + MCl 1650 ml in a beaker of 2000 ml orange) + dark or asbestos covered with HCl in a container and brown as the height f soaking: 1 wk . f drying on red dark brown hotplate / formation of 2 layers of (light orange tone) colors superimposed I the surface one is
heated to 815 C / 1 h / irradiated with rayon
W at 550.22 Mrad
mineral: &num; 43 / production process: rosé beige + accen- 1280 1 g + 5 g Pyrex / manual grinding J heated only beige age: 5 C per minute 0 # 1245 C + very light penile retention I hi cooling : SC by min juice
only in the ambient air / all in atmosphere
of natural air J irradiated with radiation W at
7.41 Mrad
mineral: &num; 15 / production process:
5 g + 27.4 q Portland cement + 13 cc water
i manual grinding J molding f hardening: beige light pink 1281 0 # 815 C # beige pinkish orange 1282 0 # 926 C dark
mineral: &num; 15 / production process: beige beige accented 1283 irradiated with radiation y at 201.6 Mrad
minerals: &num; 15 + &num; 5 / production method: deep pink beige 1284 1 g + 1 g / 1093 C / 45 min
mineral: &num; 43 / production process: beige (pink tone 1285 1g + 5g pyrex / manual grinding / warm purple accentuated) ge: 5 C per min of 0 # 1245 OC + holding pen
dant ih / cooling: 5 C per min juice
only in the ambient air / all in atmosphere
of natural air / irradiated with radiation # to
9.88 Mrad
minerals: &num; 5 + 16 / production process: light beige (tone 1286 &num; 50 g + HCl 200 ml or asbestos coated with purple rosé) HCl i soaking: 1 wk. / drying on plate
heating: .50 g + .50 g &num; 16/1037 C / 1 h
mineral: t15 f production process: pinkish orange beige 1287 2 g + Na2CO3 2 g / 0 # 815 C + 55 min at 815 C average / irradiated with Y radiation at 424.7 Mrad
mineral: &num; 15 / production method: deep pink beige 1288 0 # 760 C: 3 g + HNO3 25 ml / soaking: 3 d /
drying on a hot plate: w0 g + 50 cc
transparent polyester resin + 1% catalyst
/ manual grinding / molding / hardening /
irradiated with radiation at 5.7 Mrad
mineral: * 5 I production process:
50 g + HCl 200 ml or asbestos covered with HCl
Soaking: 1 week / drying on heating plate
f ante:
- 4 g + Na2CO3 3 g: beige pink orange 1289 0 # 648 C dark # + dark # 1290 0 # 704 C # + clear # 1291 0 # 760 C # still + clear 1292 0 # 815 C # very dark beige 1293 - 3 g + Na2CO3 2 g / 0 # 815 C (orange rosé tone) #
- 4 g + Na2CO3 3 g: beige rosé orange 1294 0 # 871 C p @ le / light turquoise green # beige pink orange 1295 0 # 926 C / turquoise green + accented
mineral: &num; 15! production process:
radiation irradiated: pinkish beige (1296 electronic tone at 302,831 brown rad) + dark pinkish beige # pinkish beige accented 1297 # at 247.6 Mrad (brown tone)
mineral: &num; 67 / production process: beige (light tone 1298 finely ground and heated powder 01482 OC: blue) .50 g + HNO3 15 ml / soaking: 2 days / exchange
on hot plate
Mineral: 15 J Production Process: Beige Green 1299 3g + HCl 15ml + HNO3 10ml J Soaking: 4-5 days
/ drying on a hotplate #
# 1300 3 g + HCl 10 ml + 15 ml water / soaking: 4-5
j / drying on a hot plate
minerals: &num; 5 + &num; 16 / production method: buff + dark 1301 .50 g + .50 g / irradiated with radiation # to that light chamois 614.204 Mrad
minerals: &num; 5 + &num; 18 * production process:
&num; 5 is heated 0 # 1037 C: clear buff i302 1 g + .5d g &num; 18 / grinding # + clear # 1303 1 g + 1 g &num; 18 / grinding # very light chamois 1304 1 g + 1.50 g & num 18 / grinding
minerals: &num; 5 + &num; 16 + &num; 98 / production method: buff 1305 .50 g + .50 g + .50 g / 926 C / 1 h
minerals: &num; 5 + &num; 93 / production method: buff 1306 .50 g + .50 g / 926 C / 1 h
minerals: * 5 + &num; 93 / production process: buff 1307 50 g &num; 5 + HCl 200 ml or asbestos covered with
HCl / soaking: 1 week / drying on plate
heating: .50 g + .50 g &num; 93/926 C / 1 h
minerals: &num; 5 + &num; 98 J production process: buff 1308 5 g &num; 5 + HC1 200 ml or asbestos coated with
HCl / soaking: 1 week / drying on plate
heating: .50 g + .50 g &num; 98/871 C / 1 h
minerals: &num; 5 + &num; 98 / production process:
&num; 5 0 # 1037 C: 50 g + HCl 200 ml or asbestos
covered with HCl and soaking: 1 wk. J drying
on hot plate: buff 1309 2 g + 2 g &num; 98/537 C / 1 h
# 1310 2 g + 6 g &num; 98/704 C / 1 h
Minerals: * 5 + # 16 / production process: Buff 1311 1 5 50 g + HCl 200 ml or asbestos covered with
HCi J soaking: 1 wk J drying on plate
heating: .50 g + .50 g &num; 16! 926 C / 1 h
mineral: 5 & production process: chamois 1312 0 # 648 C # + accented 1313 0 # 704 C # still + accented 1314 0 # 760 C
mineral: 15 J production process: buff 1315 0 # 982 OC: 3 g + HNO3 25 ml / soaking: 3 ji
# drying on hot plate # + dark # 1316 0 # 1037 C: 3 g + HNO3 25 ml / soaking: 3 d /
| drying on hot plate # still + dark 1317 0 # 1054 C: 3 g + HNO3 25 ml / soaking: 3 d /
hot plate drying
mineral: &num; 5 / production process: buff + dark 1318 2 g + Na2CO3 2 g / 0 # 871 C + 1 hr at 871 C as chamois
mineral: &num; 5 1 production process: medium chamois 1319 0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
# green HCl / soaking: 1 wk / drying on
# hotplate: 1 g + 6.50 g powder of
glass ispruce pine batch) 1 manual grinding /
deposit on a ceramic biscuit plate /
heating in an oven of 0 # 1000 C in atmos
normal phère / slow cooling in oven # + dark 1320 irradiated with radiation y to 9.83 Mrad
mineral: &num; 5 / production method: very light chamois 1321 2 g + Na2CO3 2 g / 0 # 1037 C + 1 h at 1037 C (light orange tone)
mineral: 5, production process:
2 gt Na2CO3 2 gi Ot 1037 C + 1 h at 1037 ° C
J irradiated with radiation: buff (light tone 1322 y 190.22 Mrad orange) + dark than light orange chamois chamois, light tone electronic 1323 162.431 orange rad) + dark orange chamois very light
mineral: * 5 / production process: orange chamois 1324 2 g + Na2C) 3 2 g I 0 # 760 C + 1 h at 760 C light / irradiated with electronic radiation at
302,831 mineral rad: t5 / production process:
50 g + HC1 20u ml or asbestos coated with HCl
/ soaking: 1 week / drying on heating plate
fante: I g + Na2CO3 4g: orange chamois 1325 0 # 648 Clear OC # # + orange and 1326 0 # 704 C accented
mineral: &num; 5 I production process: orange chamois 1327 2 g + Na2CO3 2 g I 0 # 760 C + 1 h at 760 C clear
mineral: * 5 / production process: light buff 1328 0 # 1037 C / irradiated with radiation y to (very orange tone 254.20 Mrad accented)
mineral: * 5 J production process: orange chamois 1329 50 g + HCl 200 ml or asbestos covered with clear HCl / soaking:

* 1 week / drying on plate
heating: 3 g + Na2CO3 1 g / 0 # 815 C
minerals: &num; 5 + &num; 98 / production method: chamois strongly 1 1330 * 5 0 "1037 C: 50 g + HC1 200 ml or asbestos orange coated with HCl / soaking: 1 week / drying
on a hot plate: 2 g + 2 g &num; 98/704 C
/ 1 h
mineral: production method: orange-colored chamois 1331 2 g + Na2CO3 2 g / 0 926 oC + 5 h at 926 ° C
mineral: &num; 5 / production process: buff (light tone 1332 1093 C / 45 min orange)
mineral: 5 I production process: buff (light tone 1333 0 # 815 C orange) @ a little + accented 1334 0 # 871 C still + accented 1335 0 # 1037 C + dark 1336 0 # 1093 C still + dark 1337 0 # 1148 C still + dark 1338 0 # 1204 C # still + dark 1339 0 # 1260 C
mineral: 15 t production method: orange chamois 1340 0 # 593 C: 3 g + HNOs 25 ml / soaking: 3 jf
drying on a chamois heating plate (light 1341 0 # 648 C: 3 g + HNO3 25 ml / soaking: 3 d / orange) drying on hotplate
mineral: &num; 5 / production method: medium chamois (ton 1342 0 # 1037 C / radiation irradiated & gamma powder, orange accented) at 614.20 Mrad
mineral: &num; 5 1 production process: orange chamois 1343 50 g + HCl 200 ml or asbestos covered with medium HCl / soaking: 1 wk. / drying on heating plate
fante: 3g + Na2Co3 1g / 0 # 871C
mineral: Production process:
3 9 + HCl 25 ml f soaking: 5 d / drying on
hotplate: orange chamois + 1344 '482 C / 2 h clear than dark orange chamois # still + clear 1345 482 C / 3 h
minerals: &num; 98 + production method: orange chamois 1346 &num; 50 # 1037 C: 50 g + HCl 200 ml or variable dark asbestos covered with HCl i soaking: 1 wk. I drying chamois + beige on hot plate: 2 g + 2 g &num; 98/815 C
/ 1 h
mineral: &num; 5 J Production method: light buff (tone 1347 50 g + HCl 200 ml or asbestos coated with accentuated HCl orange) / / soaking: i wk. i drying on turquoise turquoise chaufvert plate: ig + Na2CO3 4 gf 0 # 760 oC
minerals: &num; 5 + &num; 16 / production method: clear buff 1348 &num; 5 50 g + HCl 200 ml or asbestos coated with (pinkish reflection) HCl / soaking: 1 wk. / drying on plate
heating: .50 g + .50 g &num; 16/982 C / 1 h
minerals: * 15 + &num; 76 / production method: light rosé chamois 1349 1 g + ig / 926 C i 1 h
Minerals: &num; 15 + &num; 80 / Production Method: Light Rosy Chamois 1350 .50 g + .50 g / 0 # 1037 C
Minerals: &num; 5 + &num; 98 I production process: rosé chamois 1351 &num; 5 0 # 1037 C: 50 g + HCl 200 ml or asbestos
covered with HCl J soaking: 1 wk. J drying
on hot plate: 2 g + 2 g &num; 98/760 OC 11h
mineral: * 15 / production process: rosé chamois 1352 0 # 815 C: 3 g + HNO3 25 ml / soaking: 3 ji
drying on hot plate a little + dark 1353 0 # 871 C: 3 g + HNO3 25 ml / soaking: 3 d /
drying on heating plate still + dark 1354 0t.926 OC: 3 g + HNO3 25 ml I soaking: 3 ji
hot plate drying
mineral: &num; 15 J production process: rosy chamois 1355 0 # 593 C
1356 0 # 648 C clears 1357 0 # 704 C
to 1358 0 # 760 C
of 1359 0 # 815 C tones of 1360 0 # 871 C
1361 0 # 926 C
1362 0 # 982 C
1363 0 # 1037 C flesh # 1364 0 # 1054 C
mineral: N5 J production process:
0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
green HCl I soaking: 1 wk. 1 drying on
heating plate: rosé chamois 1365 204 C / 1 h
1366 260 C / 1 h
goes 1367 315 C / 1 h
1368 371 C / 1 h lightening 1369 426 C / 1 h
mineral: &num; 5 / production method: rosé chamois 1370 Ot1037 C: 50 g + HCl 200 ml or light green recylated asbestos HCl / soaking: 1 wk. / drying on
hotplate / 482 C / 1 h
mineral: 5 @ production process: rosé chamois 1371 0 # 1037 C: 50 g + HCl 200 ml or ashes recooked intense green HCl I soaking: 1 wk. i drying on
heating plate / 315 C / 1 h / irradiated with
radiation &gamma; at 190.22 Mrad
minerals: * 5 + &num; 98 I production process: rosé chamois 1375 &num; 5 0 # 1037 OC: 50 g + HCl 200 ml or intense asbestos covered with HCl / soaking: 1 wk. / drying on
hotplate: 2 g + 2 g &num; 98/871 C / 1h
mineral: * 15 I production process: buff (beige tone) 1373 0 # 704 C: 3 g + HNO3 25 ml / soaking: 3 d /
drying on heating plate '4- + clear 1374 Oit 760 OC: 3 g + HNO3 25 ml f soaking: 3 ji
hot plate drying
minerals: &num; 5 + &num; 98 I production process: buff (brown tone) 1375 &num; 5 0 # 1037 C: 50 g + HCl 200 ml or asbestos re
covered with HCl / soaking: 1 wk. / drying on
hotplate: 2 g + 2 g &num; 89/926 C / 1h
mineral: &num; 15 / production method: dark buff 1376 3 o + HCl 25 ml I soaking: 5 days drying on light brown; hotplate / 482 C / 1 h
mineral: &num; 5 / production method: buff (light 1377 0 # 593 C gray tone)
mineral: * 5! production process:
0 # 1037 C: chamois (gray tone) 1378 1 g + .25 g oil soot / grinding buff (gray tone 1379 1 g + .50 g oil soot / grinding + accented) # buff (gray tone 1380 1 g + .75 g of oil soot / pronounced grinding)
mineral: 5 production process: light cream beige 1381 50 g + HCl 200 ml or asbestos covered with HCl
I soaking: 1 week i drying on heating plate
fante: .50 g + Na2CO3 .50 g / 0 # 1037 C /
irradiated with radiation y at 425.65 Mrad
mineral: &num; 15 / production process:
20 g + NaOH 20 g: beige cream (tone 1382 0 # 1010 C apple green)
#
+ accented 1383 0 # 1037 C
mineral: 89 / production process: very yellow beige, 1384 3 g + 5 g pyrex; manual grinding i clear chauftrès fage: 5 C per min of 0 # 1245 OC + holding
during 1 hr cooling: 5 C per min
to the ambient air / all in atmosphere
natural air
mineral: * 5 I production process: orange-beige + 1385 3 g + HNO3 25 ml / soaking: 3 d / drying on dark as beige hotplate: .50 g + add. 1 cc very light orange ink of transparent white printing; grinding mechanics
nique; 1 glossy white paper /
irradiated with radiation at 11.4 Mrad
Minerals: &num; 5 + &num; 70 f Production method: Light orange beige 1386 1 g + 1 g J 1093 C / 45 min
mineral: &num; 5 / production method: light orange beige 1387 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: I sem. J drying on heating plate
.50 g + Na2CO3 .50 g / irradiated with
radiation &gamma; at 244.204 Mrad
mineral: * 6 i production process: beige light orange 1388 2 g + Na2CO3 2 g / 0 # 593 C + 1 h at 593 C
mineral: &num; 5 / production process: orange-beige 1389 50 g + HCl 200 ml or asbestos covered with HCl
t soaking: i wk. / drying on heating plate
fante: 3 g + Na2CO3 2 g / 0 # 871 C
mineral: * 5 i production process: orange-beige 1390 0 # 1037 C: 50 g + HCl 200 ml or asbestos recou
green HC1 / soaking: 1 week / drying on
hot plate / irradiated with radiation
at 162,431 rad
mineral: &num; 5 / production process: orange-beige 1391 5 g + H2SC4 100 ml i soaking: 2 wk. / drying
heating on hot plate / irradiated with rayon
electronically at 162,431 rad
mineral: X5 / production process: orange-beige 1392 3 g + HCl 20 ml + 5 mi 'water / soaking: 5 d /
drying in an oven at 37 C: .3 g + 50 cc
transparent polyester resin + 1%
catalyst J grinding manual J molding i deposit
in an oven for plastics at 37 C until curing
Minerals: &num; 5 + 16 / Production Method: 1393 orange-beige & 50 g + HCl 200 ml or asbestos coated with
HCl / soaking: 1 week / drying on plate
heating: .50 g + .50 g &num; 16/871 C / 1 h
mineral: production method: orange-beige 1394 2 g + HCl 5 ml + 20 ml water / soaking: 4-5 days
/ drying on a hot plate
minerals: &num; 50 + &num; 100 f production process: 1395 orange beige 4 g powder &50; deposited on one stone &num; 100
1 @ 760 C / 1 hp irradiated with X-radiation at
64.7 Mrad / color of the glaze
1396 4 g powder &50; deposited on a stone &num; 100
/ 815 OC. @ 1 hi irradiated with radiation y to
64.7 Mrad f mineral color: 15 I production process: medium orange beige 1405 2 g + Na2CO3 2 g / 0 # 760 C + ih at 760 C
/ irradiated with radiation # to64.7 Mrad
mineral: 15 / production process: orange-beige + ac-1406 2 g + Na2CO3 2 gi 0 # 760 C + 1 h at 760 C cent, luminous and I irradiated with electronic radiation to orange that beige 302,831 rad orange medium
mineral: 5, production process:
50 g + HC1 200 ml or asbestos covered with HCl
Soaking: 1 week / drying on heating plate
Fante:
- 4 g + Na2COx 2 g: beige dark orange 1407 0 # 704 C beige dark orange 1408 0 # 760 C whose orange tone 1409 0 # 815 C
I will be accentuated 1410 0 # 871 C
#
# - 4 g + Na2CO3 1 g: pink orange 1411 0 # 704 oC medium #
# beige orange (tone 1412 0 # 982 C yellow) + clear than the medium orange beige (yellow tone) + clear and + yellow 1413 0 # 1037 C
minerals: &num; 5 + 16 / production method: medium beige (1414 & 50 g + HC1 200 ml or asbestos coated with intense pinkish orange) HCl / soaking: 1 wk. / Ovum drying
heating: .50 g + .50 g &num; 16/815 C / 1 h
mineral: 5 J production process: dark beige (1415 50 g + HCl 200 ml or asbestos coated with pinkish-orange HCl) / soaking: 1 wk. / drying on heating plate
fante: 4 g + Na2CO3 2 g / 0 # 648 C
Minerals: &num; 67 + &num; 98 / Production Method: pinkish orange 1416 2 g + 2 g J 704 C / 1 hi irradiated with electronic beam at 162,431 rad
minerals: &num; 5 + &num; 53 / process of production: orange-beige (1417 1g + 1g / 1093c / 45 min red)
mineral: 5, production process:
50 g + HCl 200 ml or asbestos covered with HCl
Soaking: 1 week i drying on heating plate
f ante:
- 4 g + Na2CO3 2 g: dark beige (tone 1418 0 # 926 C orange rust) # dark beige (tone 1419 0 # 982 C orange rust) / beige (rust orange tone and dark olive green reflection) # dark beige (tone 1420 0 # 1037 orange rust) / apple green
minXral: 89 / production process: medium caramel beige 1421 3 g + 5 g pyrex / manual grinding I heated
fage: 5 C per min of 0 # 1245 OC + holding
during 1 hi cooling: 5 C per min
to the ambient air / all in atmosphere
natural air / radiation irradiation #
at 4.94 Mrad
Minerals: &num; 5 + &num; 93 / Production Method: light beige 1422 &num; 5 50 g + HCl 200 mi or asbestos coated with
HCl / soaking: 1 week / drying on plate
heating: 50 g + .05 g &num; 93/871 C / 1 h
mineral: 5 I production process: light beige 1423 50 g + HCl 200 ml or asbestos covered with HCl
/ soaking: 1 week / drying on heating plate
fante / 871 C / 1 h minerals: &num; 5 + * 98 / production process:
&num; 5 0 # 1037 C: 50 + HCl 200ml or asbestos
covered with HCl / soaking: 1 wk. I dry
heating on a hot plate: light beige 1424 2 g + 12 g * 96/704 OC '/ 1 h + light 1425 2 g + 24 g &num; 98 1 704 oC / 1 h mineral: &num; 5 I production process: beige 1426 1 g + 27.4 g Portland cement + 13 cc water
+ Na2CO3 1 g / manual grinding / molding /
durtissement / 0 # 1037 C
Minerals: # 5 + # 98 / Production Process: Beige 1427 # 50 # 1037 Oc: 50g + HCl 200ml or Asbestos
covered with HCl / soaking: 1 wk. J drying
on heating plate: 2 g + 2 g &num; 98/260 C
/ 1 h
mineral: 5, production process: beige 1428 3 g + HCl 25 ml / immediate drying on plate
heating: .3 gi 50 cc polyes resin
transparent ter + 1% catalyst / grinding
manual / molding / depositing in an oven for
plastics at 37 C until hardening
mineral: * 5 J production process: beige 1429 3g + HCi 25ml f soaking: 5d J drying in
an oven at 37 OC: .3 g + 5u cc resin of
transparent polyester + 1% catalyst I
manual grinding i molding / depositing in an oven
for plastics at 37 0C for 1 h
mineral: 15 / production process: beige 1430 0 # 982 0C: 3 g + HCl 25 minutes dipping time: 3 d /
hot plate drying
mineral: 15 J production process: beige 1431 3 g + HCl 10 ml + HNO3 15 ml J soaking: 4-5 days
J hot plate drying
mineral: &num; 67 / production process: beige 1432 finely ground and heated powder of
0 # 704 C: .2g + 50cc polyes resin
transparent ter + 1% catalyst / grinding
manual J molding i curing J irradiated at
electronic radiation at 155,082 rad
mineral: &num; 67 / production process beige 1433 finely ground powder / 0 # 482 C
minerals: &num; 5 + &num; 16 / production method: beige light gray 1434 .50 g + .50 g / 871 C / 1 hr
mineral: &num; 5 I production process: beige + dark gray 1435 3 g + HF 20 ml I soaking: 24 h / drying in gray beige one tube at 37 ° C / irradiated with clear radiation at 190.22 Mrad
mineral: &num; 15 J production process: beige medium gray 143b 1g + 6.50g glass powder (spruce pine
batch) / manual grinding i deposit on a plate
ceramic biscuit I heating in a
oven of 0 # 1000 C in normal atmosphere / re
slow cooling in the oven
mineral: &num; 15 / production method: beige light gray 1437 20 g + NaOH 20 g 1 0t982 C
mineral: &num; 67 / production process: medium gray beige 1438 .45 g + 5 g pyrex / manual grinding / heat (slight orange reflection) fage: 5 C per min of 0 # 1245 C + holding
during 1 h / cooling: 5 C per min
up to the ambient air J all in atmosphere
of natural air I irradiation with radiation
at 9.88 Mrad
mineral: &num; 5 f production process:
50 g + HCl 200 ml or asbestos covered with HCl
J soaking: 1 wk / drying on heating plate
fante: 4g + Na2CO3 4g: beige gray (light 1439 0 # 760 C red orange tone) # beige gray (light 1440 0 # 815 C orange tone rauge) / TURQUOISE GREEN cl aI r
Mineruax: 5 + 26, production method: brown beige 1441 1 g + 1 g / 1093 C / 45 min
minerals: &num; 5 + &num; 68 / production method: brown beige 1442 1 g ~ 1 g / 1093 C / 45 min
Minerals: &num; 5 + &num; 94 / Production Method: Brown Beige 1443 1 g + 1 g / 1093 C / 45 min
minerals: &num; 5 + 91 / production method: brown beige 1444 1 g + 1 g / 1093 C / 45 min (crystalline reflection)
minerals: &num; 5 + &num; 98 t production process: dark brown beige 1445 &num; 5 50 g + HCl 200 ml or asbestos coated with (pinkish tone) HCl / soaking: 1 wk. / drying on plate
heating: .50 g + .50 g &num; 98/926 C / 1 h
mineral: &num; 6 / production method: buff brown 1446 250 g + HCl 1650 ml in u beaker 2000 ml
or asbestos covered with HCl in a container
in height / soaking: 1 week / drying on
heating plate f formation of 2 layers of
superimposed colors / deep layer
is heated to 537 C / 1 h
minerals: &num; 6+ &num; 98 / production method: buff-brown 1447 &num; 6,250 g + HCl 1650 ml in a beaker of 2000
half or asbestos covered with HC1 in a tale
height and soaking: 'wk. / drying
on heating plate / formation of 2 layers
of superimposed colors / color in pro
Foundry: 2 g + 2 g &num; 98/537 C / 1 h
mineral: 15 / production method: buff brown + 1448 0 # 760 C: 3 g + HNO3 25 ml / soaking: 3 d / clear than brown drying on hot plate: .3 g + 50 cc medium buff resin transparent polyester + 1 catalyst
/ manual grinding / molding / hardening /
irradiated with electronic radiation at 155,082
rad
Minerals: # 16 + # 53 + # 98 / production method: 1449 violet brown # 53 # 760 C: 8 g = 96 g &num; 98/815 C / 1 h: bleached. 50 g + .50 g &num; 16 I grinding
Minerals: # 16 + # 53 + # 98 / production method: 1450 purple-brown # 53 # 760 C: 8 g = 96 g &num; 98 g / 815 C / 1 h: and intense that the .50 g + .50 g 16 J grinding I irradiated to brown purple whitened radiation y to 602.804 Mrad
Minerals: # 53 + # 98 / production method: brown (light tone 1451 2g + 2g / 648c / 1h purple)
Minerals: # 53 + # 98 f production process:
&num; 53 0 # / 60 C: Indian red (tone 1452 2g + 2g &num; 98 / 760c / 1h violet) #
# evolving towards 1453 2 g + 12 g 98/760 C / 1 h violet brown 1454 2 g + 24 g 98 1760 CJ 1 hr
# 1455 2 g + 2 g &num; 98 1 815 C / 1 h + dark brown 1456 2 g + 6 g &num; 98/815 C i 1 h purple still purple 1457 2 g + 24 g &num; 98/815 C / 1h + dark
Minerals: # 53 + # 93 + # 98 / production method: brown (light tone 1458 &num; 53 0 # 760 C: 8 g + 96 g &num; 99/815 CJ 1 h: purple) + pale as .50 g + .50 g &num; 93 I grinding / irradiated to the dark purple brown X-ray at 602,804 Mrad
mineral: &num; 40 / production process: dark brown (reflection 1459 1 g + i cc purple violet synthetic enamel paint) transparent for 1 auto J manual grinding I ap
on a piece of body sheet
measuring 1 x 1 "/ irradiated with z radiation at
102.4 Mrad
minerals: &num; 53 + &num; q8 i production method: dark purple brown 1460 - &num; 53 0 # 760 C 2 9 + 6 g &num; 98 1 704 CI 1 h
&Num; 1461 - 2 g &num; 53 + 2 g &num; 98 1760 CI 1 h
&Num; 1462 - &num; 53 0 # 760 ° C; 8 g + 96 g &num; 98/815 C # 1h
1463 - .50 g + .50 gi 871 OC i 1 h
Minerals: # 53 + # 93 + # 98 / production method: dark brown (light 1464 &num; 53 0 # 760 C: 8 9 + 96 9 &num; 98 I 815 OC 'I 1 h: purple tone) .50 g + .50 g &num; 93 i grinding
minerals: t53 + # 176 I production method: dark purple brown 1465 1 g &num; 53 + .50 g &num; 76 i0t 1093 C
# 1466 1 g &num; 53 + 1 g &num; 76/0 # 1093 C
# 1467 1 g &num; 53 + 1.50 g &num; 76/0 # 1093 C
minerals: t53 + t98 / production method: brown violet + dark 1468 2 g + 2 gi 760 C i 1 h I irradiated with rayon brown violet y to 424.7 Mrad
minerals: &num; 53 + &num; 76 I production method: dark purple brown 1469 1 g + 1 g 1 1010 CI 30 min (red tone)
minerals: &num; 57 + * 5th production process: violet brown (1470 tones 1 g &num; 58 + 2 g &num; 57/0 # 926 C grois)
minerals: &num; 16 + t53 i production process: head more + accen- 1471 .50 g &num; 53 + 1.50 g &num; 16/0 # 871 C killed as dead head clear
Minerals: # 53 + # 93 / Production Method: Dead Head + Dark 1472 .50 g + .50 g / .926 C i 1 hi irradiated as dead head accentuated y-radiation at 425.65 Mrad
Minerals: # 53 + # 93 / production method: dark dead head 1473 .50 g &num; 53 + g; 93 / o # 1148 C (purple tone)
Minerals: # 53 + # 98 / production method: dark dead head 1474 &num; 53 0 # 760 C: 8 g + 96 g &num; 98/815 C / lh: (Purpurin purple tone .50 g + .50 98/871 C / 1 h accented)
Minerals: # 53 + # 93 + # 98 / production process: dead head made 1475 &# 53 # 760 C: 8 g + 96 g &num; 98/815 C / 1: (pinkish purple tone). 50 g + .50 g &num; 93/871 C / lh
Minerals: # 53 + # 93 / production process: dead head accentuated 1476 .50 g + .50 g J 926 C iih (purple red tone)
minerals: &num; 16 + &num; 53 / production method: dead head (tone 1477 .50 9 &num; 53 + lg &num; 16/0 # 260 pink lilac accented) # dead head (ton 1478 .50 g &num; 53 + lg &num; 16/0 # 648 Red lilac 1479 .50 g &num; 53 + 1 g &num; 16/0 # 704 C accented) # dead head average 1480 .50 g &num; 53 + lg &num; 16 / 0 # 871 C (Light pink tone) # light dead head 1481 .50 g &num; 53 + 1.50 G &num; 16/0 # 760 C (purple pink reflection) # dead head medium 1482 .50 g &num; 53 + .50 g &num; 16/0 # 760 C (purple pink tone) 1483 .50 g &num; 53 + .50 g &num; 16/0 # 871 C # dead head (tone 1484 lg &num; 53 + .50 g &num; 16 / 0 # 648 C red) #
# dead head (tone 1485 lg &num; 53 + .50 g &num; 16/0 # 704 C purple red) i486 1.50 g &num; 53 + .50 g &num; 16 i 0 # 704 C
# 1487 1.50 g &num; 53 + lg &num; 16/0 # 704 C
Minerals: # 53 + # 93 / production method: medium dead head 1488 .50 g + .50 g / 871 cm 1 hr
(purple red tone) + accented and red 1489 irradiated with radiation # at 64.7 Mrad
minerals: &num; 16 + &num; 53 / production method: clear head 1490 1.50 g &num; 53 + lg &num; 16/0 # 260 C
(brown tone) # dead head clear 1491 1.50 g &num; 53 + lg &num; 16/0 # 648 C
(red tone) # dead head (tone 1492 lg &num; 53 + .50 g &num; 16/0 # 260 C brown) #
# dead head (tone 1493 1 g &num; 53 + .50 g &num; 16/0 # 593 oC red) #
# dead head (tone 1494 1.50 g &num; 53 + .50 g &num; 16/0 # 260 C brown)
# dead head (tone 1495 1.50 g &num; 53 + .50 g &num; 16/0 # 648 C red)
minerals: * 53 + &num; 93 i production process: deadhead (ton 1496 .50 g &num; 53 + 1.50 g &num; 93/0 # 1148 C gray with violet reflection)
Minerals: 50 + 100 / production method: light brown (light 1497 2 g &num; 50 + Na2CO3 2 g / deposit on green tone stone) 100/760 C / LH
mineral: &num; 5 / production method: pale orange-brown 1498 3 g + HND3 100 ml / soaking: 24 hi drying
on warming plate # + pale 1499 + 0 # 482 C
mineral: 15 / production method: medium orange-brown 1500 1 g + 5 g pyrex i manual grinding i heat
fage: 5 C per min of 0 # 1245 C + holding
during I h I cooling: 5 C min
to the ambient air / all in atmosphere
natural air
mineral: production method: orange-brown 1501 'Ot815 OC: 3 g + HCl 15 ml + HND3 10 ml / ml
soaking: 3 days / drying on a hot plate:
.30 g + 50 cc transpa polyester resin
annuity + 1% catalyst / manual grinding I
Ray irradiation irradiation
electronically at 155,082 rad
mineral: &num; 5 / production method: medium orange brown 1502 2 g + Na2CO3 2 g / 0 # 871 C + lh at 871 ° C
mineral: &num; 5 / production process: dark brown + brown 1503 2 g + Na2CO3 2 g / 1037 C / lh / irradiated and intense brown at # 550.22 Mrad orange medium
mineral: production method: dark orange brown 1504 5 g + HNO3 80 ml / soaking: 2 wk. / drying
on hot plate
minerals: &num; 6 + * 98 / production method: dark orange brown 1505 &num; 6,250 g + HCl 1650 ml in a 2000 beaker
ml or asbestos covered with HCl in a
height / soaking: 1 wk. / drying
on heating plate i 2-layer formation
of colors superimposed on the layer in depth
deur: 2 g + 2 g # 98/704 C / lh / irradiated
at radiation # at 555.92 Mrad
mineral: &num; 50 - production method: dark orange brown 1506 .45 gt 6.50 g glass powder (spruce pine (green batch reflection) i manual grinding / deposit on a localized plate) of ceramic biscuit i heating in a
oven of 0 # 1000 C in normal atmosphere / re
slow cooling in the oven
mineral: # 6 / production method: very orange brown 1507 stone covered with HCl 20 ml / soaking: 2 dark sem. / irradiated with radiation # at 5.7 Mrad / drying on sand bath
minerals: &num; 5 + &num; 98 / method of production: medium orange brown 1508 .50 g + .50 g / grinding irradiated with rayon (light green tone) X at 614,204 Mrad
mineral: &num; 50 / production method: orange-brown (tone 1509 lg powder inside 27.4 g green) / yellow I Portland cement + 13 cc water / manual grinding orange J molding / hardening J add: 5 g
powder on the surface of the dried cement i 0 # 871 C
mineral: # 50 J production process: orange-brown (ton 1510 27.4 g Portland cement + 13 cc water I verti! yellow J manual grinding / molding / immediate failure on orange wet cement 1 g powder I harden
addition / addition: 5 g on the surface of the cement
dried / 0 #.

871 C
mineral: production method: brown rust 1511 40 g + HCl 100 ml / soaking: 5 m. J drying
natural / irradiated with electronic radiation
to 162,431 rad
Minerals: $ 5 + # 98 / production method: brown rust 1512 i5 50 g + HCl 200 ml or asbestos covered with medium HCl I dipping: i wk. i drying on plate
heating: lg + Na2CO3 lg + 2 g &num; 98 /
926 C / lh
mineral: &num; 15 / production method: rusty brown 1513 0 # 926 C: 1 g + HNOs 40 mi / natural drying intermediate between irradiated with X-radiation at 425.65 Mrad average and dark
mineral: &num; 5 + &num; 98 / production method: brown rust 1514 &num; 5 50 g + C1 200 ml or all-dark asbestos covered with HCl i soaking: 1 wk. J drying
on hot plate: ig + Na2CO3 1 g +
&num; 98 1 9/926 C / 1 hr
mineral: &num; 6 / production method: rusty brown / 1515 4 g + HNO3 50 ml / soaking: 4 wk. / blue drying (light refiet on green heating plate)
mineral: &num; 50 / production process:
4 g powder deposited on a pile on a piece of steel
stainless steel measuring "xl": caramel brown 1516 815 C / 20 min / immediate withdrawal + dark 1517 871 C / 20 min / immediate withdrawal
mineral: &num; 5 / production method: brown car # dark mel 1518 5 g + HNO3 80 ml / soaking: 2 wk. / drying
on a hot plate: .50 g + Na2CO3 .50 g
/ 982 C / lh
Minerals: # 50 + # 98 / Production Process:
10 g + 10 g / crushed and spread over
porcelain: dark caramel brown 1519 0 # 815 C # caramel brown (tone 1520 0 # 871 C orange yellow, vart reflection) + clear as the dark
#
a lot + intense 1521 0 #.

926 C
mineral: &num; 50 / production process:
lg + Na2CO3 lg / crushed and distributed over
porcelain: brown caramel orange 1522 0 # 926 C
# 1523 0 # 1037 C
mineral: &num; 84 / production method: amber brown + dark 1524 stone coated with paste / 65 C / 2 h / irraque light amber brown immediate diation in the hot state with rayon
puts at 2.26 Mrad
mineral: &num; 84 / production method: amber brown still 1525 peanut / 65 C / 2 h / re + dark immediate chilling at -20 C / 2 h / then,
irradiation while the coated stone is
-20 C to radiation at 2.26 Mrad
mineral: &num; 84 / production method: amber brown 1526 piarre heated to 65 C / 2 h / immé deposit
diat at -20 C / 2 h / immediate irradiation
at -20 C with radiation at 2.26 Mrad
mineral: &num; 84 / production method: amber brown (reflection 1527 stone heated to 65 C / 2 h / cooled pro
yellow) gressively to the ambient air / then, radiated
radiation exposure at 2.26 Mrad
Minerals: # 50 + # 98 / Production Process:
10 g + 10 g / crushed and spread over
porcelain: amber brown (tone 1528 OT 1093 C orange yellow) # amber brown (tone 1529 0 # 1121 C orange yellow green)
mineral: &num; 84 / production method: amber brown (reflection 1530 stone heated to 65 0C J 2h J deposit imméorangé) diat in mineral wool and irradiation
in the hot state with radiation at 2.26 Mrad
mineral: * 5 / production method: dark amber brown 1531 0 # 1037 C: 50 g + HCl 200 ml or asbestos recou (green red tone) HCl / soaking: 1 wk. / drying on
hot plate: 1 9 + 5 g pyrex J grinding
manual / heating: 5 C per minute until
1245 C + hold for 1 hour J cooling
5 C per minute to the ambient air /
all in natural air atmosphere / irradiation
at radiation # at 9.88 Mrad
minerals: &num; 50 + &num; 98 / production method: red amber brown 1532 10 g + 10 g / milled and spread over the (accented yellow tone) porcelain / 0 # 982 2 C
mineral: &num; 84! production process: light amber brown 1533 paste-coated stone J 65 oC / 2 h / re (gray tone) ambient air cooling / irradiation
radiation at 2.26 Mrad
mineral / num; 5 / production method: very rosy brown, 1534 0 # 1037 C: 50 g + HCl 200 ml or asbestos clear green HCl clearing J dipping: 1 wk. / drying on
hotplate: .50g + Na2CO3 .50g /
982 C / 1 h
Mediums: # 6 + # 98 / Production Process:
&num; 6 25 g + HCl 1650 ml in a beaker of 2000
ml or asbestos covered with HCl in a tale
height / soaking: 1 wk. / drying
on heating plate J formation of 2 layers
of superimposed colors / the layer in
color: light pinkish brown 1535 2 g + 2 g &num; 98/260 C / 1 h
# 1536 2 g + 2 g &num; 98/704 c / 1 hr
minerals: * 5 + &num; 98 I production method: medium red brown 1537 &num; 5 50 g + HCl 200 ml or asbestos covered with HCl
J soaking: 1 wk J drying on heating plate
fante: 1 g + Na2CO3 1 g + 3 g &num; 98/926 C / 1h
Minerals: No. 5 + 98 Production Method: Brown (light tone 1538 &num; 53 O 760 C: 8 g + 96 g &num; 98/815 C / 1 h red violet) + / irradiated with radiation g at 424.7 Mrad clear that the launched
Minerals: 53 + * 98 f Production process: brown (red tone 1539 &num; 53 0 # 760 C: 3. g + 12 g &num; 98/704 c / 1 h purple) + clear that dark # + red 1540 &num; 53 0 # 760 C 2 g + 24 g &num; 98/704 C / 1 hr
Minerals: &num; 6 + &num; 98 / Production Method:
6 250 g + HCl 1650 ml in a beaker of 2000
ml or asbestos covered with HCl in a con
standing height J soaking: 1 wk drying
on heating plate / formation of 2 layers
of superimposed colors: brown (red tone 1541 - surface color: 2 g + 2 g &num; 98 f purple) + clear 704 CJI hf radiation irradiation y dark at 195.92 Mrad # brown (red tone 1542 - color deep: 2 g + 2 g * 98 J purple) + clear 704 C fih than the dark
mineral: &num; 50 / production process
Minerals: # 6 + # 98 / Process Production: 1548 light brown & 6,250 g + 1650 ml HCL in a 2000 beaker
ml or asbestos covered with HCl in a tale
height / soaking: 1 em. / drying
on heating plate / formation of 2 layers
of color superimposed / the color in
deur: 2 9 + 24 g &num; 98/704 C 1 1 h
minerals: t50 + 100 J production method: light brown 1549 2 g &num; 50 + Na2CO3 2 g / deposit on a stone
&num; 100/815 C / 1 h
mineral: 50 X production process: brown 1550 4 q powder deposited on a piece of brass
measuring 1 "x 1" / 760 C / 20 min / cooling
1 brown slow-drying # brown 1551 4 g powder on a piece of paper
galvanized measuring 1 "x 1" / 760 C / 20 min
/ slow cooling in the oven
mineral: 15 I production method: medium brown 1552 3 g + HNO3 25 mi J soaking: 4-5 d / drying
on hot plate # + clear 1553 3 g + HNO3 20 ml + HC1 5 mi I soaking: 4-5 days
! hot plate drying
mineral: 5 t production process: pronounced brown 1554 O3 1037 C: 50 g + HCl 200 ml or asbestos recou
green HCl / soaking: 1 week / drying on
hotplate / 0 # 1037 C
mineral: 15 production process: dark brown 1555 irradiated with radiation at 484.704 Mrad
minerals: &num; 15 + # 126 / production method: dark brown 1556 1 g + 1 g / 1093 C / 45 min
minerals: &num; 6 + &num; 98 / production method: black brown 1557 1 g + 1 g + Na2CO3 1 g / 871 C / 1 h
mineral: &num; 6 / production method: light brown ocher 1558 2 g + Na2CO3 2 gf 0 # 760 C + 1 h at 760 C (green reflection)
mineral: &num; 6 J production process: brown ocher (tone 1559 2 g + Na2CO3 2 g / 704 C / 1 h / irradiated with orange) radiation # at 190.22 Mrad
mineral: &num; 50 J production process: brown ocher (tone 1560 1 g + Na2CO3 1 g / milled and spread on red) porcelain / 0 # 982 C
mineral: &num; 5 - production process: chocolate brown at 1561 2g + Na2CO3 2 9/0 # 926C + 1h at 926C medium milk (pinkish tone)! irradiated with radiation at 550.22 Mrad
Minerals: &num; 5 + &num; 98 / Production Method: Chocolate Brown at 1562 &num; 5 5 g + H2SO4 100 ml / soaking: 2 wk. / medium milk {slight drying on a hot plate: 2 g + 2 g &num; 98 1 pinkish tone) 704 C # 1 h / radiation irradiated # to
550.22 Mrad
minerals: &num; 5 + &num; 98 / production method: chocolate brown at 1563 &num; 5 50g + HCl 200ml or asbestos coated medium milk (gray tone, HCl J soak: 1 week / dry on the skin
heating: 3 g + Na2CO3 1 g + 1 g &num; 98 J
926 C / 1 h
mineral: i5 i production method: chocolate brown at 1564 5 g + H2SO4 100 ml J soaking: 2 wk. J medium milk (light drying on heating plate / irradiated gray tone) radiation d at 550.22 Mrad
mineral: &num; 6 / production method: chocolate brown 1565 250 g + HCl 1650 ml in a 200 ml beaker
or asbestos covered with HCl in a container
in height f soaking: 1 sen. f drying on
hot plate i 2 layer formation,
superimposed colors J the layer in depth
deur: 260 C - 1 h
mineral: &num; 5 / production method: chocolate brown 1566 50 g + HC1 200 ml or asbestos covered with medium HCl / soaking: 1 wk. / drying on heating plate
50 g + Na 2 CO 3 .50 g + HNO 3 40 ml
soaking: 5 days J separation of liquid and
solid / drying on sand bath / irradiated
radiation at 424.7 Mrad
minerals: &num; 6 + &num; 98 / production method: chocolate brown 1567 * 6,250 g + HCl 1650 ml in a beaker of 2000 dark half or asbestos covered with HCl in a tale
height / soaking: 1 sen. drying
on heating plate / formation of 2 layers
of superimposed colors i the surfa layer
this: 2 g + 2 g &num; 98/815 C / 1 h / irradiated
at radiation # at 550.22 Mard
mineral: 215 / production process: chocolate brown 1568 0 # 926 c / irradiated with radiation # at 424.7 dark Mrad
mineral: * 24 / production process: dark chocolate brown 1569 ig + 5 g pyrex i manual grinding i heat
Bright orange ezones fage: 5 C per min of 0 # 1245 C + holding
Iton yellow)) for 1 h / cooling: 5 C per min
to the ambient air / all in atmosphere
natural air
mineral: &num; 50 / production process:
27.4 g Portland cement + 13 cc water i
manual grinding; immediate molding / deposition of 1
g powder on wet cement J harden
addition of 5 g powder on the cement
dried: dark chocolate brown 1570 0 # 926 C + dark 1571 0 # 982 C
mineral: &num; 50 / production process:
1 g powder incorporated into the mass of 27.4 g of
Portland cement + 3 cc water / manual grinding
/ molding / hardening f addition of 5 g of
powder on the dried cement: dark chocolate brown 1572 0 # 926 C # + dark 1573 0 # 982 C mineral: &num; 50 i production process: dark chocolate brown 1574 4 g powder deposited on a steel plate
stainless and heated to 1093 C / 45 min
minerals: &num; 26 + &num; 50 / production method: dark chocolate brown 1575 .75 g &num; 50 + .25 g &num; 26 are ground and dropped
on a stainless steel plate and heated
at 1093 C / 45 min
Minerals: 50 + # 68 / Production Method: dark chocolate brown 1576 .75 g # 150 + 25 g &num; 68 are ground and dropped
on a stainless steel plate and heated
at 1093 C / 45 min
mineral: &num; 24 / production process: very yellow orange 1577 1 9 + 5 g pyrex / manual grinding I heating: bright J brown chocolate 5 gold per min 0 # 1245 C + holding for very dark 1 h / cooling: 5 Gold per min up
the ambient air I all in atmosphere
natural air / radiation irradiation #
at 9.88 Mrad
mineral: &num; 67 / production method: dark chocolate brown 1578 powder: 0 # 704 oC + 4 h at 704 C: 1 9 + 5 9 (purpurin ton) pyrex / manual grinding J heating: 5 C
by min of 0 # 1245 C + hold for 1 h /
cooling: 5 C per minute until air
ambient / all in a natural air atmosphere
/ radiation irradiation y at 9.88 Mrad mineral: &num; 50 J production process: chocolate brown (tone 1579 1 g + 5 g pyrex I manual grinding / heating amber red) very ge: 5 C per min 0 # 1245 C + maintenance: 1 h dark I cooling: 5 C per minute until air
ambient J all in a natural air atmosphere
! Radiation irradiation # at 9.88 Mrad
mineral: &num; 30 / production process: very bright red broom / 1580 1 g + 5 g pyrex / manual grinding / chocolate warmer (tone ge: 5 C per min of 0 # 1245 C + hold: 1 h orange) very dark / cooling: 5 C per min until air
amblant I all in a natural air atmosphere
/ Radiation irradiation # at 9.88 Mrad
mineral: &num; 50 J production process: medium chocolate brown 1581 1 g + Na2CO3 1 g / crushed and spread over the (light red tone) porcelain / 0 # 871 C
mineral: J production process: dark chocolate brown 1582 4 g + HNO3 50 ml, soaking: 4 wk. / drying (gray tone) on heating plate / irradiated with radiation
# to 550.22 Mrad
mineral: &num; 50 J production process: dark chocolate brown 1583 1 g + 5 g pyrex i manual grinding i heated (gray tone and reflection age: 5 C per min of 0 # 1245 C + pened) 1 hour J cooling : 5 C per min juice
only in the ambient air / all in atmosphere
natural air
mineral: &num; 89 i production process: burnt umber 1584 3 g + 5 g pyrex f manual grinding / heatingamitoyen between the age: 5 C per min of 0 # 1245 C + penmoyen hold and the dark dant 1 hi cooling : 5 C per min juice
only in the ambient air / all in atmosphere
natural air
mineral: &num; 89 / production method: burnt umber 1585 about 150 g of glass paste (sodalime) is intermediate between the melt collected in the medium furnace and the dark (1200 C) on a metal rod i 1 g &num; 89
is sprinkled on the glass and then the whole thing is
reintroduced into the furnace and melted at the
flame at 1200 CJ then, the collection is de
stained metal rod / irradiation with
radiation at 9.88 Mrad
mineral: * 5 / production process: light gray brown 1586 1 g + ó.50 g glass powder {spruce pine
batch) J manual grinding i deposit on a plate
of ceramic biscuit / heating in a
oven of Ot1000 C in normal atmosphere
slow cooling in the oven
minerals: &num; 6 + &num; 98 / production method: light gray brown 1587 &num; 6,250 g + HCl 1650 ml in a 2000 beaker
ml or asbestos covered with HCl in a tale
height / soaking: 1 wk. J drying
on heating plate / formation of 2 layers
of superimposed colors / color in pro
Foundry: 2 g + 6 g &num; 98/704 C / 1 h
mineral: 5 I production process: brown gray + dark 1588 0 # 871 OC: 1 9 + 1 cc printing ink as transparent white clear I mechanical grinding I 1 im
pressure on glossy white paper i irradiated at
radiation at 22.8 Mrad
mineral: 50 I production method: dark gray brown 1589 2 gg + Na2CO3 2 g / 760 C / 1 h J irradiated at
X radiation at 424.7 Mrad
mineral: &num; 5 / production method: beige gray + clear 1590 2 g + Na2CO3 2 g / irradiated with radiation # to that light beige gray 550.22 Mrad
mineral: &num; 5 / production method: light beige gray 1591 3 g + HF 20 ml / soaking: 24 h / drying in
an oven at 37 C
mineral: &num; 5 / production method: beige gray 1592 irradiated powder with radiation #: 484.704 Mrad
mineral: &num; 5 / production method: beige gray 1593 0 # 537 C
Minerals: &num; 5 + &num; 98 / Production Method: beige gray 1594 .50 g + .50 g + Na2CO3 .50 g / 871 C / 1 hr
Minerals: &num; 5 + &num; 93 / production method: beige gray 1595 .50 g + .50 g / 871 C / 1 hr
mineral: 5 / production process: beige gray (light 1596 0 # 537 C: 1 g + 1 cc printing ink green tone) transparent white / mechanical grinding / 1 im
pressure on glossy / irradiated white paper
radiation at 22.8 Mrad
mineral: &num; 67 / production process:
powder finely ground and heated to: very light brown gray 1597 760 C / 1 h with metallic luster # + dark # 1598 815 C / 1 h
# 1599 0 # 815 C # still + dark 1600 0 # 871 C
mineral: &num; 15 / production method: light brown gray 1601 3 g + HF 20 ml / soaking: 24 h / drying in
an oven at 37 C
mineral: &num; 5 / production process: gray (light tone 1602 3 g + H2904 20 ml / soaking: 24 h / brown drying) on hotplate
Minerals: 50 + 100 / production process: gray brown 1603 4 g powder deposit 50 on a stone 100
/ 760 C / 1 h / irradiated with radiation # to
424.7 Mrad / color of the glaze
mineral: &num; 67 / production process: gray brown 1604 finely ground powders + heated from 0 # 593 C:
.50 g + H2SO4 15 ml / soaking: 2 days / drying
slow on a hot plate: .07 g + 6 cc
concrete polymer + 0.18 cc catalyeu + 1.5
thousandth of a g of cobalt 6% + 2 g cement Port
land / manual grinding / molding / curing / irradiated with radiation # at 18.85 Mrad
mineral: 15 t production method: medium brown gray 1605 g / h H2SO4 25 ml i soaking: 24 h / drying
on hot plate
mineral: production method: medium brown gray 1606 15 g + H3PO4 100 ml / soaking: 3 wk. /
drying on a hot plate (hum.)
mineral: &num; 67 J production process: gray brown adjoined 1607 powder finely ground and irradiated with rayon between medium and ment # at 484.704 Mrad the dark
mineral: * 67 J production process: gray brown (reflection 1608 finely ground powder + heated from 0 # 704 C: yellow green) .20 g + 50 cc transpa polyester resin
rent + 1% catalyst I manual grinding /
molding / curing / irradiated with rayon
electronically at 305,082 rad
Minerals: &num; 53 + &num; 93 + &num; 98 / production method: gray-brown (reflection 1609 2 g &num; 53 + 1 g &num; 98 + 1 g * 93 J 815 C / I h pinkish purple) + dark that means # medium brown gray 1610 2 g &num; 53 + 1 g &num; 98 + 2 g &num; 93/815 C / 1 hr (pinkish purple reflection)
minerals: &num; 16 + t53 + * 98 production process: medium brown gray 1611 ig &num; 53 + 2 g &num; 98 + I g &num; 16 J 871 CJ 1 h (purple pink reflection) #
# 1612 1 g &num; 53 + 1 g &num; 98 + 2 g &num; 16/871 C / 1 hr
mineral: 77 / production process: gray (lilac tone 1613 0 # 1037 C: .50 g + HNO3 100 ml / soaking: 4 pronounced with years / drying on hot plate pinkish reflection)
mineral: 38 production process: violet gray (moire 1614 1 g + 5 g pyrex / manual grinding olive heating) + ge: 5 C per min of 0 # 1245 C + maintenance accentuated for 1 hf cooling: 5 C by min juice
only in the ambient air J all in atmosphere
natural air / radiation irradiation #
at 9.88 Mrad
mineral: 6 J production process: 1615 green gray 250 g + 1650 ml HC1 in a 2000 ml beaker
or asbestos covered with HC1 in a container
in height I soaking: 1 wk. J drying on
hot plate I formation of 2 layers of
superimposed colors / surface layer:
irradiated with electronic radiation 162, 431rad
mineral: &num; 67 / production process: gray green 1616 finely ground + heated powder of 0 # 593 C:
.50 g + HNO3 15 ml f soaking: 2 d / drying
slow on hot plate * ante: .20 g + 50 cc
transparent polyester resin + 1% cata
lyser. manual grinding J hardening
is lying ! irradiated with electronic radiation at
155,082 rad
mineral: 7 / production process: green gray 1617 3 g of finely ground powder + HNO3 30 ni /
soaking: 3 days drying on a hot plate:
.07 9 + 6 cc concrete polymer + 0.18 cc
catalyst + 1.50 thousandth of g of cobalt 6%. +
2 g Portland cement t manual / soft grinding
aging / curing J irradiated with radiation
at 18.85 Mrad
Minerals: # 5 + # 93 / production process: very yellow gray 1618 &num; 5 5g + HCl 200ml or asbestos covered with clear # HCl I soaking: 1 sec. I drying on plate
# heating: .50 g + .50 g &num; 93 / grinding #
# 1619 irradiated with radiation # at 63.984 Mrad
mineral: 5 / production process: gray (yellow tone 1620 irradiated stone with radiation at 65.704 Mrad + accented)
mineral: &num; 15 / production method: light gray (1621 reflection 20 g + 20 g / 0 NaOH green 955 C)
mineral: * 67 / process of production: very light gray, to 1622 g of stone covered with 20 nor HNO3 I trem metallic luster page: 2 wk. / irradiated with radiation y blank 11.4 Mrad / drying on sand bath / neck
their stone
mineral: * 50 J production process: gray 1623 deposit of 4 g powder on a piece of aluminum
nium measuring 1 "x 1" / 760 C / 1 hr
slow cooling in the oven
mineral: &num; 50 I production process: gray! brown 1 1624 1 g + Na2CO3 1 9 I ground and distributed in green porcelain crucible lids /
0 # 704 C
Minerals: 50 + 98 J Production process: gray 1625 10 g + 10 g / milled and distributed in
porcelain crucible lids /
0 # 704 C
Minerals: 50 + 100 / production method: marbled gray, 1626 deposit of 4 g of powder 50 on a piece of 100/815 C / 1 h / radiation irradiated
gamma at 424.7 Mrad / color of the glaze
mineral: 5 / production process: qris metallic 1627 stone coated bread dough / 0 # 704 C dark
mineral: &num; 5 / production process: metallic gray + 1628 finely ground powder and irradiated with the dark rayonne that the gray ment # at 124.704 dark metallic Mrad
Mineral: 106 J Production Process: Metallic Gray 1629 3g + 5g Pyrex J Manual Grinding I Heated (Blue Reflect) + Ge: 5 C per Min of 0 # 1245 "C + Pouch Holder Than Gray 1 1 hi cooling: 5 C per min. light metal chloride than in ambient air i all in atmosphere
of natural air / radiation irradiation #
at 9.88 Mrad
Minerals: # 50 + # 98 # Production Process: Metallic Gray 1630 10g + 10g Grinded and split into Brown Tone) Porcelain Crucible Locks J 0 # 648 C
mineral: &num; 5 i production process: medium iron gray 1631 0 # 1037 C: 50 9 + HCl 200 mi or asbestos recou
green HCl J soaking: 1 wk. J drying on
hotplate: 1 g + 5 g pyrex / broya
manual ge i heating: 5 "C per min from
0 # 1245 C + hold for 1 h / cooled
5 C per minute to ambient air!
all in a natural air atmosphere
mineral: * 6 J production process: a) dark iron gray 1632 4 g + HsPO4 50 ml dipping 2 wk. Drying b) amber brown on hot plate ihum.) J color of
a) solid b) liquid
mineral: &num; 67 J production process: medium iron gray 1633 finely ground + heated powder of 0 # 593 C: (indigo blue reflection) .50 g + HCl 15 ml f soaking: 2 d drying
on heating plate: .15 g + 16 cc poly
concrete sea + 0.18 cc catalyst + 1.50
thousandth of g cobalt 6% + 2 g cement
Portiand J manual grinding / molding / cured
radiation irradiated at 18.85 Mrad
mineral: &num; 67 / production method: medium iron gray 1634 2 g + Ma2CO3 2 g / 0 # 482 C + 1 h at 482 C
(green / irradiated reflection to electromagnetic radiation at localized) 302, 831 rad
mineral: &num; 67 / production process:
stone coated with bread dough and heated i: black gray 1635 871 C / 30 min #
+ black 1636 871 C / 1:30 h
mineral: &num; 67 I production process: black gray 1637 stone covered with bread dough I 871 0C i 30
min: 10 9 + HNO3 80 mi f soaking: 1 sen. i
drying on a hotplate / maintaining
the boiling state until complete drying J
color of the stone
mineral: &num; 67 / production process: black gray 1638 pIerre irradiated with UV laser radiation pen
4 min on a surface of 0.40 cm2 with
a 0.180 Joule laser energy having a flux
of 1.3 x 103 W / cm2 to give a
total energy of 432 Joules
mineral: &num; 67 / production process: black gray accented 1639 irradiated stone with radiation # to 604.53 11rad
mineral: &num; 83 / production process: a) black blue 1640 0 # 1037 C: 1 g + H3PO4 80 ml / soaking: 2 b) gray sem. / drying on a hot plate (hum.) /
color of a) liquid b) solid
mineral: &num; 95 / production process: black (light reflection 1641 1 9 + 5 9 pyrex J manual grinding i hotplug) ge: 5 C per min from 0 # 1245 C + holding pen
1 hour / cooling: 5 C per minute
only in the ambient air / all in atmosphere
natural air / radiation irradiation d
at 7.41 Mrad
mineral: &num; 95 / production process: black (blue reflection 1642 ig + 5 g pyrex J manual grinding / warmagris accentuated) ge: 5 C per min of 0 # 1245 C + holding pen
1 hour / cooling: 5 C per minute
than the ambient air i all in atmosphere
natural air / X-ray irradiation
at 9.88 Mrad
mineral: &num; 35 / production process: ai black smokes 164o 1 9 + H3PO4 80 mi i soaking: 2 wk. f drying b) white on hotplate (hum.) / color of
a) liquid b) solid
Minerals: # 53 + # 98 / Production Process:
1 g + 1 g + Na2CO3 2 g: black soot (light 1644 0 # 648 C green tone) 1645 0 # 704 C
# 1646 0 # 760 C
minerals: &num; 5 + &num; 98 / production process:
50 9 * 5 + MCI 200 ml or asbestos covered with
MCl J soaking: 1 wk / drying on plate
heating: black 1647 - 1 g + 1 g &num; 98 + Na2CO3 2 g / 926 C / 1 h
# 1648 - 1 g + 1 g &num; 98 + Na2CO3 3 g / 926 C / 1 h
minerals: &num; 6 + &num; 98 / production process: black 1649 i 9 + 1 9 + Na2CO3 1 9 i 926 CI 1 h
mineral: * 6 I prduction method: black 1650 4 g + H3PO4 50 ml / soaking: 4 wk. / drying
on hot plate (hum.)
mineral: * 8 / process of production: ai black 1651 1 g + H3PO4 50 mi ï soaking: 2 wk. i drying b) white on hotplate (hum.) / color of
a) liquid b) solid
mineral: &num; 9 J production process: a) black 1652 4 g + H3PO4 80 ml / soaking: 2 wk. / drying b) gray on hotplate (hum.) / color of
a) liquid b) solid
mineral: 32 production process: a) black 1653 1 g + H3PO4 50 ml i soaking: 2 wk. i drying b) white on hotplate (hum.) / color of
a) liquid b) solid
mineral: 50 I process of production: black 1654 deposit of 4 g powder on a piece of copper
measuring 1 x 1/760 cm 20 min f cooling
slow drying in the oven # black 1655 deposit of 4 g powder on a piece of sheet metal
black measuring 1 "x 1" / 760 C / 20 min /
slow cooling in the oven
minerals: &num; 50 + * 98 / production process: black 1656 lu g + 10 g / crushed and distributed on necks
vercies of porcelain crucibles f 0 # 760 C
mineral: &num; 51 / production method: a) black 1657 12 g + H3PO4 40 ml / soaking: 2 wk. / sechab) brown on hot plate (hum.) / color of
a) solid b) liquid
mineral: &num; 57 / production method: black 1658 stone irradiated with electronic radiation to
164,800 rad, then to 155,082 rad, then to
radiation at 360 Mrad
mineral: &num; 57 I production process: black 1659 stone irradiated with radiation B at 28.5 Mrad,
then to neutron radiation at 1012 neu
trons / cm2 / sec for 40,000 sec1 *
mineral: &num; 57 / production method: black 1660 stone irradiated with neutron radiation at
10t2 neutrons / cm2 / sec for 30,000 sec,
then radiation at 102.4 Mrad
mineral: &num; 67 / production method: a) black 1661 2 g + H3PO4 20 ml / soaking: 3 d / drying b) dark gray on hot plate (hum.) / color of
a) liquid b) solid
mineral: 79 / production process: a) black 1662 0 # 1037 C :. 20 g + H3PO4 50 ml / soaking: 3 db) white J drying on hot plate (hum.) F neck
their a) liquid b) solid
mineral: &num; 79 / production process: a) black 1663 4 g + H3PO4 80 ml / soaking: 2 wk. / drying b) white on hotplate (hum.) / color of
a) liquid b) solid
mineral: &num; 99 / production process: a! black 1664 2 g + H3PO4 5 m! I soaking: 2 weeks / drying b) white on hot plate (hum.) / color of
a) liquid b) solid
mineral: &num; 99 / production process: a) black 1665 0 # 1037 C: .30 g + H3PO4 80 ml / soaking: 2 b) gray sem. J hot plate drying (hum.) /
color of a) liquid b) solid
mineral: &num; 107 / production method: a) black 1666 6 g + H3PO4 50 ml / soaking: 2 wk. / drying b) white on hotplate (hum.) / color of
a) liquid b) solid
mineral: &num; 57 / production process: deep black 1667 irradiated stone with radiation # at 555.02
Mrad. then to neutrons at 1012 neutrons / cm2
/ dry for 40,000 sec1 * 1 *. The sample, previously irradiated with gamma radiation and subsequently
neutron radiation, indicates three times less radioactivity
than that which has received the same neutron irradiation
without having been previously irradiated with gamma rays.

Claims (11)

 1. A colored powder that can be used as a pigment, characterized in that it is obtained by at least one physical treatment by irradiation carried out before or after application in a material to be colored, and in that it is chosen from the group consisting of mineral powders of different colors numbered as follows in the Table appended to the description: 22, 58, 63, 64, 73, 74, 76, 82, 90, 101, 104, 105, 110, 120, 165, 172, 173, 184, 225, 239, 256, 844, 326 , 342, 364, 404, 423, 470, 476, 484, 499, 505, 513, 538, 539, 624, 625, 626, 662, 666, 730, 748, 793, 794, 795, 799, 814, 902 , 904, 905, 906, 907, 1010, 1041, 1042, 1043, 1044, 1046, 1049, 1050, 1051, 1055, 1096, 1105, 1112, 1113, 1126, 1127, 1174, 1193, 1230, 1255, 1283 , 1296, 1297, 1301, 1459, 1508, 1545, 1546, 1555, 1590, 1592, 1607, 1620, 1628, 1638, 1639, 1658, 1659, 1660 and 1667. 2. Use of a colored powder as defined in claim 1 as a pigment in a material selected from the group consisting of plastics, synthetic resins, inks, paints, paper pulp, glass, metal coatings, concrete and other heavy construction materials. A method for modifying the color of a material capable of undergoing irradiation, characterized in that a mineral powder is applied to or in said material as a pigment and subjected to said material and the applied pigment. on or in the at least one irradiation at an intensity and for a time sufficient to obtain the required color change. 4. Process for the preparation of a colored powder that can be used as a pigment, characterized in that at least one physical treatment is carried out by irradiation with a mineral powder, the colored powder thus obtained being chosen from the group consisting of the mineral powders of different colors numbered as follows in the Table appended to the description: 22, 58, 63, 64, 73, 74, 76, 82, 90, 101, 104, 105, 110, 120, 165, 172, 173, 184, 225, 239, 256, 844, 326, 342, 364, 404 , 423, 470, 476, 484, 499, 505, 513, 538, 539, 624, 625, 626, 662, 666, 730, 748, 793, 794, 795, 799, 814, 902, 904, 905, 906 , 907, 1010,  1041, 1042, 1043, 1044, 1046, 1049, 1050, 1051, 1055, 1096, 1105, 1112,  11, 1126, 1127, 1174, 1193, 1230, 1255, 1283, 1296, 1297, 1301, 1459,  1508, 1545, 1546, 1555, 1590, 1592, 1607, 1620, 1628, 1638, 1639, 1658,  1659, 1660 and 1667. 5. Process according to claim 4, characterized in that the mineral powder is irradiated with gamma rays, X-rays, electrons or lasers, the powder thus prepared being chosen from those numbered as follows in FIG. Table appended to the description: 90, 120, 172, 173, 284, 326, 364, 404,470,476,484,499, 1010, 1041 to 1044, 1096, 1112, 1113, 1126, 1127,  1230, 1283, 1296, 1297, 1545, 1546, 1555, 1592, 1607, 1620, 1628, 1638 and 1639. 6. Process according to claim 4, characterized in that the mineral powder is subjected to several irradiation treatments consisting of an irradiation with electrons and gamma rays, an irradiation with electrons and then with radiation. X, an irradiation with electrons then with neutrons, or an irradiation with gamma rays then with neutrons, the powder thus prepared being chosen among those numbered as follows in the Table appended to the description: 82, 104, 110, 165,239, 1055,1174 , 1193, 1658, 1659, 1660 and 1667. 7. Process according to claim 4, characterized in that (a) the mineral powder is mixed with a powder of at least one other compound selected from the group consisting of the other minerals, the oxides, the metal salts of a nature organic, organic substances of vegetable or animal origin; and (b) at least one irradiation treatment is carried out on at least one of the above two powders before or after mixing them. 8. Method according to claim 7, characterized in that the treatment mentioned in step (b) is carried out on at least one of the powders only before mixing them, the mixture of powders thus prepared and treated being chosen from those numbered as follows in the attached Table in Appendix 342, 624, 625, 626, 793, 794, 795, 814, 904, 905, 906, 1049, 1050 and 1051. 9. Method according to claim 2, characterized in that the treatment mentioned in step (b) is carried out on at least one of the powders before mixing them, the mixture of powders thus prepared and treated being based on two minerals, a mineral and a powder of vegetable origin, or a mineral and a powder of animal origin and being selected from among those numbered as follows in the Table attached at the Appendix: 626, 906, 1051. 10. Process according to claim 7, characterized in that the treatment mentioned in step (b) is carried out on at least one of the powders before mixing them, the mixture of powders thus prepared being composed of at least three powders and being selected from those numbered as follows in the Attached table attached: 342, 624, 625, 793, 794, 795, 814, 904, 905, 1049, 1050. 11. Process according to claim 7, characterized in that the treatment mentioned in step (b) is carried out after mixing the powders, the mixture of powders thus prepared and treated being chosen from those numbered as follows in the table below. attached as appendices: 539, 1301, 1508, 1 590.