NL8104409A - DIALING MEDIA WITH VARIABLE SENSITIVITY AND INFORMATION REGISTRATION. - Google Patents

Description

* _ έ »VO 232¾ χ 'Betr .: Dialing medium with variable sensitivity and information registration.

The invention relates to an optical recording medium and an information recording having areas of different recording sensitivity, wherein information can be recorded in the areas of higher sensitivity without information being recorded. 5 registered in areas of lower sensitivity.

U.S. Patent 4,097,895 of 27 June 1978 describes a two-layer ablative recording medium having a reflective layer covered with an absorbent layer, the thickness of the absorbent layer being chosen to be. reflectivity of the recording medium is reduced. The absorbent layer is melted or removed during recording, thereby changing the reflectivity of the recording medium. During playback, the differences in reflectivity between disturbed and undisturbed portions of the optical recording medium are detected optically and converted into an electrical signal representative of the recorded information.

United States Patent 4,216,501 of August 5, 1980 describes a three-layer optical recording medium in which a transparent spacer layer is disposed between the reflect first layer and the absorbent layer as used in the recording medium of United States Patent Specification 4,097 * 895. The thickness of the absorbent layer is related to the thickness of the spacer layer and to the optical constants (refractive index and quench coefficient) of the "reflective layer, spacer layer and absorbent layer such that the reflectivity of the recording medium is reduced .. During the recording process, the absorbent layer is melted or removed, thereby forming an opening in this layer, as a result of which the reflectivity of the recording medium is changed.As an alternative, it is possible To deform the absorbent layer without opening an aperture, or the optical properties of the absorbent layer may change so as to change the reflectivity.

In either of these cases, the optical recording medium 8104409 * -2- * from point to point on the recording medium has a substantially uniform recording sensitivity. The shape and dimensions of a change in the absorbent layer »e.g. an aperture therein thus depends on the shape and dimensions of the light beam used in recording.

U.S. Patent No. 6,36TT of November 2, 19T9 discloses a video disc configuration in which the surface is sensitive to recording in a spiral recording track, said recording surface being non-sensitive in the areas 20 located between adjacent tracks. This can be accomplished by using an unmodulated high power laser effective to write the unwanted surface areas of a blank recording medium with uniform thermal sensitivity. According to an alternative method, the disc described can be used as a master for the photolithographic fabrication of discs with illustration-sensitive spiral tracks. This additional processing is undesirable since the sensitive surface must have a high degree of perfection in order for the information recorded therein to be faithfully reproduced.

It would be desirable to have a optical recording medium with a locally varying recording sensitivity, such that, the recorded change in the absorbing layer is independent of the shape and coverage of the recording light beam, and no further processing after formation of the absorbent layer. is required.

An optical recording medium to which the present invention pertains comprises a substrate having a plurality of recesses formed in a major surface thereof with an absorbent layer 3® disposed over the substrate and filling recesses so that first and second regions are formed in the optical recording medium. The recording sensitivity of the optical recording medium in the first areas is considerably greater than the recording sensitivity of the optical recording medium in the second areas.

The invention also relates to an information record with an information track registered therein which has the form 8104409 # + m -3- of a series of subregions in the first regions whose optical properties differ from those of the remaining part of the first areas and of the second areas.

The invention will be further elucidated hereinafter with reference to the drawing. In the drawing: Fig. 1 is a schematic perspective view illustrating an optical recording medium according to the invention; FIG. 2 is a schematic diagram illustrating a cross-sectional view of a portion of a first embodiment of the invention; Fig. 3 is a diagram illustrating a cross-sectional view of a portion of a second embodiment of the invention; Fig. k is a diagram illustrating a cross-sectional view of a portion of a third embodiment of the invention; Fig. 5 is a diagram illustrating a cross-sectional view of part of an information record according to the invention; Fig. 6 is a diagram illustrating a cross-sectional view of a portion of a second embodiment of the information record; and FIG. J is a diagram illustrating a cross-sectional view of a portion of an optical recording medium with recesses of changing depth.

The optical recording medium 10 shown in Fig. 1 comprises a substrate 12 having a major surface 1h, an absorbent layer 16 being provided on this substrate 12 over this major surface. The optical recording medium 10 comprises first regions 18 which, compared to second regions 19 constituting the remainder of the optical recording medium, have a higher absorbance * at the wavelength of a recording light beam. By way of illustration, the first regions 18 are shown in the form of grooves 20 or alternatively may be arranged in the form of a checkerboard pattern 22. As explained in more detail below, the first regions 18 may be arranged in any form desired by the user to record formation 3 in the optical recording medium because of the higher absorbency 8104409 ΐ *.

In these regions, a recording light beam incident on the optical recording medium 10 will preferably record information in the form of a change in the optical properties of the recording medium in the first regions 18 as opposed to. the second 5 areas. 20 overlapped by the beam. Such a change may take the form of a non-reversible recording, e.g., because an opening is formed in the optical absorbent layer 16; as an alternative, this change may take the form of one. reversible registration, e.g. in that the degree of crystallization 10 of the absorbent layer 16 is reversibly changed.

A first embodiment 30 of an optical recording medium according to: the invention shown in Fig. 2 comprises a substrate 12 having a main surface 11 +; a number of recesses 32 ,. which extend from the main surface 1¼ over a certain distance in the substrate 12, wherein a number of islands 31 + is formed between the recesses 32; and an absorbent layer 36 which fills in the recesses S, extending across the islands 3¼ located between the recesses 32. The absorbent layer contains two parts; a first part 1 + 0 which fills the recesses 32 and is thicker than a second part 1 + 2 which lies over the islands 31 + which are located between the recesses. The top surface 1 + 1 + of the light absorbing layer 36 is flat and may be covered with an upper coating 1 + 6.

In the configuration shown in Figure 3, the. element and 25 having a counterpart in the second embodiment 50 and the first embodiment 30 of the invention, denoted by the same reference numerals. The second embodiment 50 of the invention differs from the first embodiment 30 in that a reflective layer 52 over the main surface 11 + is located including the recesses 32 and the islands 3l + located therebetween; and an absorbent layer 51 +, which fills the recesses 32 and can also pass over that part of the reflective layer 52. lying above the islands 3l + between the recesses 32. The absorbent layer then contains two parts, n.1. a first portion 56 that fills the recess thicker than a second portion 58 that 8104409. · V r * -5- overlying islands between recesses ".

The flat top surface 60 of the light absorbing layer 5k may be covered with an upper coating.

In the configuration shown in Figure k, those elements 5 also appear in the third embodiment 70 and. in the second embodiment 50 of the invention, designated by the same reference symbols. The third embodiment 70 of the invention differs from the second embodiment 50 in that it is a spacer layer. 72 fills the recesses 32 of the main surface 4, this layer 10 also being able to overlay the reflective layer 52, which is located above the islands 3k. The spacer layer thus includes a first portion Jk in the region of the recesses in the main surface 1k and a second portion j6 which is thinner than the first portion and overlies the islands 3k between the recesses 32. An absorbent layer 78 of substantially uniform thickness overlies the surface. 80 of the spacer layer 72. The third embodiment 70 of the invention is further distinguished from the second embodiment 50 in that a head layer 82 can overlay the surface 8k of the light absorbing layer 78. A top coat may overlie the head layer 82 or, in another configuration where no head layer is present, this top coat may overlay the light absorbing layer 78.

The substrate 12 may be formed of a plastic material such as polyvinyl chloride or (poly) methyl methacrylate, and typically this substrate is formed as a disc. The recesses can be formed in a main surface of the substrate 12, namely by making a replica of a master with recesses present therein by giving a relief to the surface 1; alternatively, the recesses can be formed during compression molding or casting of the disk. Typical of the recesses is that they have a depth of about 5 nanometers and about 200 nanometers.

It will be appreciated that the description of the major surface as having recesses formed therein includes both pits in the surface and parts extending boats the surface of the disc. The function of the wells or raised parts 8104409

* V

t -6- is the same n.1, giving optically sensitive coatings with variable thickness.

In the first embodiment 30 shown in Figure 2, the depth of the recesses 32 is selected such that the thickness of the absorbent layer 3 which fills the recesses 32 is approximately the thickness; that is. requires col to achieve an equilibrium between absorption and reflection to give a higher sensitivity, or is preferably somewhat smaller than this thickness. If the. depth less than this thickness will bring any additional thickness above the thickness of fir to the desired value. Typical for the depth of the recesses 32 is a value, between about $ and about 10 nanometers for the first embodiment 30.

In the second and third embodiments of Figures 3 and k, the depth of. the recesses selected such that the thickness of the layer filling the recesses is approximately equal to the thickness required to minimize the local reflectivity of the optical recording medium, or preferably slightly less than this thickness. If the depth is less than this thickness, any additional thickness above the recess will bring the thickness to the desired value. Typical of the depth of the recesses 32 is the value between about 20 and about 80 nanometers for the two layer structure of the second embodiment. 50 of FIG. 3, and for the three layer structure of the third embodiment 70 of FIG. 1, a typical depth value is between about 30 and about 200 nanometers. As will be explained in more detail below, the preferred thickness of the absorbent layer or spacer layer and absorbent layer depends on the properties of the materials from which the layers are formed.

The reflective layer 52 of the embodiment of Fig. 3 · 30 preferably reflects a substantial portion, preferably at least 50%, of it. the incident light at the wavelengths used for recording and playback and this layer is typically formed of a metal, such as aluminum or gold, and Siev has a high reflectivity at these wavelengths. The thickness of the reflective layer 52 has a typical value between about 8104409-7 and 6θ nanometers and this layer can be deposited on the surface 1 op of the substrate including the recesses by vacuum evaporation. As an alternative, a single or a multi-layer dielectric reflector can be used.

The absorbent layer 36 of the first embodiment 30 of FIG. 2 and the absorbent layer 5 of the second embodiment 50 of FIG. 3 are made of a material that absorbs light at the wavelengths of the light beams used in recording and playback, and which can be deposited on the surface 1 or 10 on the reflective layer 52 such that the recesses 32 in the main surface 11 of the substrate are preferably filled. When the recesses 32 are filled, excess material can be one-thin. layer over the recesses 32 and the islands 3 between the recesses 32, so that a smooth, continuous top surface of the absorbent layer is obtained. In each embodiment, the absorbent layer can be composed of an organic dye dissolved in a • solvent and then * precipitated by spinning techniques. Suitable dyes, incorporated in a binder, are given by an 8% direct volumetric solution of phenylazo-1-naphthylamine in Shipley 1350 B photoresist material dissolved in 25-1 with 2-methoxyethyl acetate which is precipitated by spinning. This material is useful at a wavelength of one; recording or playback light source of approximately U88 nanometer.

The top coating hé is composed of a material in which the wavelengths of the light beams used for recording and playback are substantially transparent. An upper coating with a thickness between about 0.05 and about 1 mm is useful. Dust particles that adhere to the top surface of the top coating are then far from the focal point of the optical recording and reading system, so that the effect on recording and reading information is greatly reduced. A useful material for this application is a silicone resin that can be deposited using spinning techniques.

The thickness of the absorbent layer of the second embodiment 50 of FIG. 3 is related to the optical constants 8104409 * s * -8- of the reflective layer and the absorbent layer and the top coat, if present, that it reflects power of the optical recording medium in the first regions is reduced and preferably reduced to a minimum corresponding to the anti-5 reflection state. The optimal values of the thickness of the absorbent layer can be calculated, e.g. sub-application of the matrix method, as discussed in "Optical Properties of Thin .Solid Films" by O.S. Heavens, Dover Publications., Inc *, Hew York, 19 ^ 5, biz · 69,

The thickness of the absorbent layer with a reduced reflectivity has a typical value between about 20 and about 100 nanometers.

The thickness of the absorbent layer 51 then varies over the surface of the optical recording medium, it being understood that the thickness is in the areas of the optical recording medium. recesses 32 is greater than the locations of the regions of the islands 3k. The first minimum of reflectivity at the wavelengths used for recording and playback will be above the recesses. When the recesses are filled, the thickness of both the second portion 58 located above the islands 3 ^ and of. the first portion 56 rises above the recesses 32 '. As the thickness of the second portion increases, the reflectivity of this portion will decrease, while the reflectivity of the first portions after it passes through a minimum will begin to increase. Thus, by controlling the coating thickness above the second portions, the areas of lower reflectivity and higher sensitivity can be achieved either above the recesses 32 or above the. islands 3 ^ are located. The thickness of the second portion is preferably reduced to a minimum and the portions located above the recesses 32 are the areas of lower reflectivity and higher sensitivity.

In the third embodiment 70 of the invention, as shown in FIG. U, it is the thickness of the spacer layer 72 that is varied. The spacer layer consists of a material which is substantially transparent at the wavelengths of the light beams 35 used for recording and playback and which material can be deposited on the light-reflecting layer 52 such that the recesses 32 in the surface of the substrate should preferably be filled so that a first portion Jb of the spacer layer is formed. After the recesses are filled, the thickness of the first portion 7 ^ and a second portion J6 above the islands will increase 3¼. A suitable spacer material is poly-methyl-styrene dissolved in toluene and precipitated by spinning techniques.

The light absorbing layer 78 overlying the spacer layer 72 contains a material that absorbs light at the wavelengths of the light beams used for recording and playing.

Suitable materials for this layer are titanium, rhodium, tellurium, seleniurir, tellurium or selenium-based alloys, arsenic trisulfide and arsenic triselenide. Such materials can be precipitated using vacuum evaporation. After being exposed to the at-15 atmosphere, some of these materials will oxidize, leaving an absorbent layer which is clearly thinner than the originally deposited layer. This effect can be compensated for by depositing a layer whose thickness is greater than the desired thickness at which the. subsequent oxidation then returns the effective thickness to the desired value.

The thickness of resp. the spacer layer 72 and the absorbent layer J8 is selected such that the reflectivity of the first or second portions of the optical register medium is reduced and these thickness measurements are calculated taking into account the optical properties of the reflective layer, the spacer layer and the absorbent layer, as well as the head layer and top coating, if any, as well as the wavelengths of the light beams used for recording and playback. A typical value for the thickness of the spacer layer whereby reduced reflectivity is obtained is between about 20 and about 200 nanometers and the thickness of the absorbent layer is between about 3 and about 50 nanometers. The sensitivity over the surface of the data record can then be varied by varying the thickness of the spacer layer; the spacer layer is thicker 35 in the region of the recesses 32 than in the region of the islands 3 ^ 8104409 -10- * *

As is the case with the absorbent layer of the second embodiment 50 of FIG. 3, the first minimam of the reflect may have one power above the recesses. When the recesses are filled with the spacer material, the thickness of the second portion 76 of the spacer layer above the islands 3¾ will increase, as will the thickness of the first portion Tk in the recesses. As the thickness of the second portion increases, the local reflectivity of the optical recording medium in this area will decrease, while the reflectivity of the first portion will begin to increase after the minimum has been reached. Thus, by controlling the thickness of. the spacing layer over the second portion is achieved so that the areas of lower reflectivity and higher sensitivity may be either above the recesses 32 or above the islands 3¼. The thickness of the second portion of the spacer layer is preferably reduced to a minimum so that the areas of the first portion are 7 inches above the recess. 32 the areas are where reflective power is smaller and the sensitivity is greater.

The head layer 82 may overlie the top surface. 8U from. the light absorbing layer 78 · The purpose of the top layer is to prevent the top coating b6 from being damaged by thermal influences when a high melting point material such as titanium or rhodium is used as the material for the absorbent layer 78. However, Indian for the absorbent layer J8, a material with a low melting point is used, such as eg tellurium, selenium, or an alloy containing any of these materials, the headcoat is not necessary to prevent the topcoat k6 from being damaged by thermal action.

However, if the head layer 82 and the spacer layer 72 are formed of materials which act to prevent cracks or other permanent deformations from forming in the absorbent layer 78, a reversible recording, i.e. a recording, can be erased in the absorbing layer J8. and reapplied, are made. Suitable materials for the absorbent layer 78 in this embodiment are tellurium, selenium, tellurium or selenium based alloys, arsenic trisulfide and arsenic triselenide.

8104409 * »m -11-

Suitable materials for the top layer can be used and are effective cm. to prevent a reversible recording from being made, e.g. silicon dioxide, silicon monoxide, titanium dioxide and tellurium dioxide. Such materials can be deposited using. electron beam vapor deposition techniques. A typical value for the thickness of the head layer, which is prevented. Openings or other deformations in the absorbent layer are comprised between about 50 and about 500 nanometers.

It should be noted that if it is desired to record information reversibly, the top coating and the head 82 should also be substantially transparent at the wavelength of a light beam used for erasing and the absorbent layer. J8 should be absorbent at the wavelength of this light beam used for erasing.

The recesses in the surface of the disc can be made in many different patterns, such as those illustrated in Figure 1. The recesses can be in the form of a continuous, circular or spiral groove in the disc surface, so that the optical recording medium above the groove 20 is thicker than at the islands between the grooves. If the sensitivity of the optical recording medium is then greater at the area above the groove than at the area above the islands, the light beam overlapping both the groove and the islands on either side of this groove will provide information. preferably register in the groove instead of at the location of the islands on either side thereof. Alternatively, a series of recesses may be arranged in spaced apart circles or spirals, with recesses and islands alternating along the direction of track 30. In such a case, the recesses may either have the same length in each track, or may extend by an equal angular distance, which means that their length is greater the further away from the center of the disc.

Thus, in the first case, information will be recorded in the disc and played at a varying frequency, however, at a constant 8104409 rv-12. Recording elements, while in the second case, the information may be recorded and played back. with a constant frequency, but with a varying recording element size. If the sensitivity of the optical recording medium above the recesses is greater than above the islands, a light beam overlapping a recess like the islands present along the track will record information preferably only in the area of the recess.

Another possibility is a checkerboard pattern, in which a trackside recess is surrounded by island areas, both along the track and in a direction perpendicular to the track.

Fig. 5 shows a two-layer information recording medium 90 with an information track recorded therein. Those elements that are for it. information recording medium 90 and the recording medium 50 15 shown in. Fig. 3, common, have the same reference symbols. It. The information recording medium shown has recesses in the form of a series of recesses along a track with island regions located between the recesses. Information is recorded in the form of a series of openings 92 in the absorbent layer 5 *, wherein the presence or absence of an opening 92 as well as the distance between openings is indicative of the recorded information. Alternatively, the openings may be formed above the island regions 3 ^.

Fig. 6 shows a three-layer information recording medium 100 with an information track recorded therein. Those elements common to the recording medium 100 and the three-layer recording medium 70 of FIG. U have the same reference numerals. Information is recorded in the form of a series of regions 102 in the absorbent layer Jd, the optical properties of which differ from the rest of the absorbent layer. These regions may either be in the form of a non-reversible information of the absorbent layer, or may be given as a reversible change in the optical properties of the absorbent layer, such as e.g. arises from a change in the degree of crystal formation of the ab-35 sorting layer 78. The presence or absence of a change in the optical properties of the absorbing layer 8104409 -13- results in a change in the reflectivity of the recording medium , the length and distance between these areas being indicative of the recorded information.

It should be noted that if the light beam used for recording overlaps the areas of less sensitivity, the power density of this beam is sufficiently large, the change of the absorbing layer indicative of the recorded information can also take place in the second areas with lower 10 sensitivity *

The optical recording medium according to the invention has areas of different recording sensitivity due to the variable thickness of the layers. These thicknesses are always caused by the presence of recesses in the substrate surface. During the fabrication of the substrate, information in the optical recording medium can be pre-recorded by either forming recesses according to a particular spatial distribution, or. by varying the depth of the recesses. E.g. the depth of a portion of a spiral or circular groove can be modulated to form a third region whose reflectivity differs from the reflectivity of the first and second regions. This information may e.g. are used for track identification, to indicate the beginning or end of a track, or to provide synchronization data. Similar information coding schemes can be applied to other embodiments of the recesses. Those elements common to the optical recording medium 110 of FIG. 7 and the optical recording medium 50 shown in FIG. 3 have the same reference numerals. The recesses 112 and 114 extend for various distances into the interior of the substrate 12, thereby forming the third region.

During the operation of an optical recording, reading or erasing system, the light beam is centered on the information track. With the optical recording medium treated in this application, the light beam is also centered during the recording process on the first areas of higher sensitivity. If the 8104409 -aA reflectivity for the first and second regions is different, this difference can be used to produce a signal proportional to the placement of the light beam in a direction transverse to the track. This signal can be used 5- cm to the position of the beam, with respect to

* P

takes the track, correct it.

«S> - 8104409

Claims (23)

Optical recording medium, characterized by a substrate (12) with a main surface in which a number of recesses (32) are arranged; and an absorbent layer (36) which overlies the main surface (1 * 0 and fills the recesses (32), and which absorbs light at the wavelength of 5 a light beam used for recording and reading »thereby allowing the recording medium to first (18) and second (19) regions are formed such that the recording sensitivity of the recording medium in the first regions (18) is greater than the recording sensitivity of the recording medium in the second regions (19). Optical recording medium according to claim 1, characterized by a reflective layer (52) disposed between the substrate (12) and the absorbing layer (5 * 0) and through which a significant portion of the incident light at the wavelengths of the front the recording and reading of used light beams is absorbed, the thickness of the absorbing layer (5 * 0 being chosen such that the reflectivity of the recording medium valid in the first regions (18) is reduced. Optical recording medium according to claim 2, characterized by a spacer layer (72) arranged between the reflective layer (52) and the absorbent layer (78) and which spacer layer fills the recesses (32), the thickness of the spacer layer ( 72) and the absorbent layer (78) is such that the reflectivity of the recording medium 25 applying to the first regions (18) is reduced. Λ. Optical recording medium according to claims 1, 2 or 3 », characterized in that said recesses (32) extend over a distance with a size between about 5 nanometers and about 200 nanometers from the main surface (1 * 0 in the substrate (12) stretch out. Optical recording medium according to claim 1, characterized in that said substrate (12) is formed from a plastic material. Optical recording medium according to claim 2, characterized in that the thickness of the absorbent layer (5k) in the first regions (18) is 8104409. . "16" is such that the reflectivity is minimized. Optical recording medium according to claim 3, characterized in that the thickness dimensions of the distance layer (72) and the absorbing layer (78) in the first regions (18) are such that the reflectivity 5 * is minimized. Optical recording medium according to claim 1, characterized by a thick top coating (k6) overlaying the absorbent layer (36). Optical recording medium according to claim 3, characterized by a top layer (82) which overlays the absorbent layer (78) and a thick top layer (½) which overlays. top layer. (82) is lying there. 10. Optical recording medium. according to claims 1 or 2. characterized in that the absorbent layer (36, 5¾) is composed of an organic material. 11. Optical recording medium according to claims 3 or 9, characterized in that the absorbent layer (78) is formed from a material selected from the group consisting of titanium, rhodium, tellurium, selenium, on counterium based alloys »selenium based '" "alloys, arsenic trisulfide and arsenic triselenide► Optical recording medium according to claim 1, characterized in that the recesses (32) are in the form of a groove (20) in a major surface (i) of the substrate (12). Optical recording medium according to claim 1, characterized in that the recesses (32) are formed as a series of alternating first (18) and second (19) areas. 25 i. Optical recording medium according to claim 1, characterized in that for a part of the recesses (Uk) the depths over which they extend in the substrate (12) is different from that for the remaining recesses (112), so that a third region is formed with a reflectivity different from the reflectivity 30 applicable to the first (18) and the. second (19) areas. Information record with an information track recorded therein, characterized by a substrate (12) having a major surface (i) containing a number of recesses. (32) are formed; an absorbent layer (5k), which overlays the main surface (1k) and fills the recesses 35 (32), which layer absorbs light at 'the wavelength of a light beam serving for recording and reading »whereby in the 8104409 ** ► A -IT recording first (18) and second (19) areas are formed such that the recording sensitivity in the first areas (18) is greater than the recording sensitivity in the second areas (19), the information track comprising a series of the first areas (92) of which 5 have optical properties different from the rest of the first areas (18) and the second areas (19) *, the length and distance of the first areas (92) having different optical properties being indicative for the registered information. 16. Information recording according to claim 15, characterized by a reflective layer (52) disposed between the substrate (12) and the absorbent layer (5 * 0) and which layer at the wavelengths of the light beams used for recording and reading absorbs a significant portion of the incident light, the thickness of the absorbing layer (5 * 0 being chosen to reduce the reflectivity of the recording in the first regions (18). Information record according to claim 16, characterized by a spacer layer (72) arranged between the reflective layer (52) and the absorbent layer (78) and filling the recesses (32), the thickness dimensions of the spacer layer (72) and the absorbent layer (78) is such that the reflectivity in the first regions (18) is reduced. Information registration according to claims 15, 16 or 17, characterized in that said recesses (32) extend over a distance 25 with a size between about 5 nanometers and about 200 nanometers from the main surface (1 * 0 in the substrate ( 12). Information registration according to claim 15, characterized in that the substrate (12) is formed from a plastic material. Information registration according to claim 16, characterized in that the thickness of the absorbent layer (5¼) in the first regions (18) is such that the reflectivity is minimized. Information registration according to claim 15 or 16, characterized by a thick top coating (½) which lies over the absorbent layer (5 * 0). 22. Information registration as claimed in claim 17, characterized by 8104409. -18- that the thickness dimensions of the spacer layer (T2) and the absorbent layer (78) in the first regions (18) are such that the reflectivity is minimized. Information registration according to claim 17, characterized by a top layer (82) overlaying the absorbent layer (78) and a thick top layer (½) overlaying the top layer (82). 2U ... Information registration according to claims 17 or 23 »with the *. . characterized in that the absorbent layer (78) is formed from a material selected from the group consisting of titanium, rhodium, tellurium, selenium, tellurium-based alloys, selenium-based alloys, arsenic trisulfide and arsenic triselenide. Information record according to claim 15, characterized in that the recesses (32) are formed in the form of a groove (20) in the main surface (11) of the substrate (12). Information recording according to claim 15 *, characterized in that the recesses (32) are formed as a series of alternating first (18) and second (19) areas. 27. Information registration according to claim 15, characterized in that a part of the recesses (1)) applies that the depth thereof, which extends into the substrate (12), differs from the depth over which the other recesses ( 112) extend therein to form a third region of the optical properties different from the optical properties of the first (18) and second (19) regions. 8104409