CN1865150A - Nano transitional metallic oxide preparation method - Google Patents
Nano transitional metallic oxide preparation method Download PDFInfo
- Publication number
- CN1865150A CN1865150A CN 200510046478 CN200510046478A CN1865150A CN 1865150 A CN1865150 A CN 1865150A CN 200510046478 CN200510046478 CN 200510046478 CN 200510046478 A CN200510046478 A CN 200510046478A CN 1865150 A CN1865150 A CN 1865150A
- Authority
- CN
- China
- Prior art keywords
- transition metal
- metal salt
- micelle
- mixture
- salt
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
Links
Images
Landscapes
- Catalysts (AREA)
Abstract
This invention discloses a method for producing nanometer transition metal oxide. The procedures comprise: solubilise the melting transition metal salt in the mixture of hydrocarbon component and surfactantto form the molten salt-in-oil super solubilising colloidal group, which limits the transition metal hydroxide generated by the reaction of molten salt and precipitant in the colloidal group, so as to avoid the increase of particle size and narrow the particle size distribution range. and then obtain the nanometer transition metal oxide by cleaning, drying and burning. This invention is characterized of high yield and purity,with low cost of surfactant and hydrocarbon component. Besides, the process is simple and is adapted for industrial mass production.
Description
Technical field
The present invention relates to a kind of preparation method of nano-metal-oxide, relate in particular to a kind of preparation method of nano transition metal oxides.
Background technology
The nano transition metal oxides particle grain size is generally between 1~100nm, because of it has excellent macroscopic properties such as electricity, magnetic, light, mechanics and chemistry, be widely used aspect fine ceramics, ultraviolet screener, piezoelectric, photoelectric material, efficient catalytic agent material, the magneticsubstance.
Nano titanium oxide has ultraviolet ability of very high absorption and peculiar colour effect, can be widely used in fields such as sunlight screening skin-protecting product, plastic membrane product, woodenware protection, transparent durable finish paint, fine ceramics, catalyzer automobile finish paint.Titanium dioxide is again the carrier of solid super acid catalyst, and alternative liquid acid is used for technological processs such as alkylation, esterification.Nano-titania particle still is efficient photodissociation catalyzer, can be used for sewage disposal.
Nano zircite can be used for preparing super acids, synthesising gas systeming carbinol, synthetic gas preparing isobutene, isomerization reaction, chemical sensor, fuel cell electrode material, self cleaning enamel and hydrogen-storing material.
Nano-nickel oxide and cobalt oxide are the activity of such catalysts components, active ingredient especially for hydrogenation catalyst, not only can be directly as the nanoscale catalyzer, can also be supported on other oxide compound or the molecular sieve as active ingredient, but prepared sizes are even, the supported nano catalyzer that is evenly distributed.
At present, the existing preparation method of nano transition metal oxides particulate mainly is the precipitator method.Because the distinctive shortcoming of the precipitator method itself, promptly the particle diameter of nano-oxide is wayward, and distribution range is wide, easily reunites etc.Disclose to disclose with nickel salt and the sedimentary method of amine carbonate such as CN1075467C and prepared the ultra micron nickel oxide with zirconium oxychloride and the sedimentary method of sodium hydroxide, CN1037957C.It is the nickel oxide particle method of precipitation agent preparation that CN1114639A discloses with the nickelous nitrate ammonium oxalate, and the granularity of particle is less than 1 μ m, and grain fineness number is less than 500 , and particle is too big.
CN 1192991A discloses a kind of employing Preparation by Uniform Precipitation nano zine oxide method, utilizes urea to do the precipitation from homogeneous solution agent, but hydrolysis temperature height (122~126 ℃), the easy polymerization of urea need be carried out in autoclave, and the production control difficulty is big, yield poorly, still do not solve agglomeration traits.
CN 1334243A discloses the method that reverse micro emulsion prepares nano zircite, and the consumption of required tensio-active agent, hydro carbons and water is big in this method, and output is extremely low, and separation difficulty, and dosage of surfactant is big, the cost height.
Summary of the invention
For overcoming weak point of the prior art, the invention provides a kind of new method for preparing nano transition metal oxides, it is few that this method has dosage of surfactant, the product purity height, the productive rate height, nanoparticle is monodisperse status, the characteristics that particle size distribution range is narrow.
The contriver finds through a large amount of experiments, the inorganic transition metal salt of fusion can be solubilized in hydrocarbon component and the water-in-oil-type surfactant mixtures, form super solubilising nanometer micelle, control reaction with the nanometer micelle, reaction, the weathering process of inorganic transition metal salt and precipitation agent are all carried out in the nanometer micelle, thereby produce nano transition metal oxyhydroxide.
Based on above-mentioned design, the preparation method of nano transition metal oxides of the present invention comprises the steps:
(1) hydrocarbon component, VB value are mixed less than 1 tensio-active agent and cosurfactant;
(2) nano transition metal oxyhydroxide micelle is made by one of following method:
Method one: the fused transition metal salt slowly joins in the mixture of step (1) gained, is mixed to form evenly super solubilising micelle; Add precipitation agent then, under 50~120 ℃ of temperature, carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method two: the fused transition metal salt is slowly added in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle; In confined conditions, below the ammonia critical temperature, be generally the critical temperature of 30~ammonia, in above-mentioned micelle system, add precipitation agent liquefied ammonia and carry out neutralization reaction, or in confined conditions,, in above-mentioned micelle system, feed ammonia and carry out neutralization reaction at 30~300 ℃, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method three: use precipitation agent and all or part of transition metal salt to mix the post-heating fusion, slowly join in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle; Again remainder fused transition metal salt is added in the above-mentioned system; Under airtight condition, resulting micelle system is carried out the precipitation from homogeneous solution reaction under 70~200 ℃ of temperature, in 4~8 hours reaction times, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
(3) with the nano transition metal oxyhydroxide of step (2) gained,, obtain nano grade transition metal oxide compound of the present invention then through washing, oven dry and roasting.
Wherein water adds with crystal water and/or free-water form in step (1) and/or step (2);
Used transition metal salt is two or more in the inventive method step (2), and it is at least a when being the low melting point transition metal salt, also can after forming super solubilising micelle, add fused low melting point transition metal salt in the micelle system, mix, and then carry out next step, concrete process is as follows:
Method four: the fused transition metal salt slowly joins in the mixture of step (1) gained, is mixed to form evenly super solubilising micelle; Again fused low melting point transition metal salt is added in the above-mentioned micelle system, mixes, add precipitation agent then, under 50~120 ℃ of temperature, carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method five: the fused transition metal salt is slowly added in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle; Again fused low melting point transition metal salt is added in the above-mentioned micelle system, mixes; In confined conditions, below the ammonia critical temperature, be generally the critical temperature of 30 ℃~ammonia, in above-mentioned micelle system, add precipitation agent liquefied ammonia and carry out neutralization reaction, or in confined conditions, 30~300 ℃, in above-mentioned micelle system, feed ammonia and carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method six: use precipitation agent and transition metal salt to mix the post-heating fusion, slowly join in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle; Again fused low melting point transition metal salt is added in the above-mentioned micelle system, mix, under airtight condition, resulting micelle system is carried out precipitation from homogeneous solution be neutralized into glue under 70~200 ℃ of temperature, gelation time 4~8 hours, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Used transition metal salt is inorganic transition metal salt among the present invention, can be a kind of inorganic salt, it also can be the mixture of plurality of inorganic salt, the melting range of used transition metal salt is 50~300 ℃ in method one, method two, method four and the method five, and the melting range of used transition metal salt and precipitant mix thing is 50~300 ℃ in method three and the method six.The fusing point of described low melting point transition metal salt is in-100~50 ℃ of scopes.
Weight with the mixture of step (2) gained is benchmark, the consumption of transition metal salt (butt), precipitation agent and water is 60wt%~96wt%, be preferably 85wt%~96wt%, the water yield is the 100wt%~350wt% as the theoretical water requirement of reaction water, be preferably 100wt%~300wt%, most preferably be 100wt%~200wt%, the consumption of precipitation agent is the 100wt%~300wt% of theoretical requirement, the consumption of tensio-active agent is 0.1wt%-8wt%, better be 0.5wt%-5wt%, preferably 0.8wt%-3wt%; The consumption of hydrocarbon component is 3wt%~30wt%, better is 3wt%~15wt%, preferably 4wt%~8wt%; The consumption of cosurfactant is 0~2.0wt%, better is 0~1.0wt%, preferably 0~0.5wt%.
The theoretical requirement of precipitation agent is meant to be had in the presence of enough reaction water, makes transition metal salt just in time generate the weight of the required precipitation agent of corresponding oxyhydroxide fully.
Among the present invention, water main is used as a kind of reactant and participates in reaction, makes the corresponding oxyhydroxide of transition metal salt and precipitation agent reaction generation.In addition, inorganic transition metal salt adds entry in melting process, also can play the effect that reduces fusing point.Theoretical water requirement as reaction water is meant under the certain situation of transition metal salt amount, just in time makes the transition metal salt complete reaction generate the required water yield of corresponding oxyhydroxide.Water can adopt following one or more modes to add: a, add entry in step (1), b, adopt the form of the inorganic transition metal salt that contains crystal water to add in step (2), c, add entry in inorganic transition metal salt melting process.The adding mode of water is not limited to aforesaid way, can adopt the precipitation agent aqueous solution such as method one and method four, can also form at the mixture of inorganic aluminate and step (1) gained in method one, method two, method four and the method five in the even colloidal process and to add or to add after forming even colloid, method three and method six also can form at the mixture of inorganic aluminate and precipitation agent eutectic and step (1) gained in the even colloidal process or behind the even colloid of formation and add or the like.Method one and method four preferably adopt the precipitation agent aqueous solution, and contain the inorganic aluminate of crystal water and/or add entry in the inorganic aluminate melting process; Method two, method three, method five and method six preferably adopt the inorganic aluminate that contains crystal water and/or add entry in the inorganic aluminate melting process.
Transition metal described in the step (1) is one or more in the transition metal in the 4th and five cycles, is preferably in titanium, iron, nickel, manganese, zirconium, copper, vanadium, chromium, cadmium, gold, ruthenium, rhodium, tungsten, palladium, silver, platinum, yttrium, molybdenum, zinc and the cobalt one or more.Transition metal salt is inorganic salt, is preferably to contain crystal water or do not contain in crystal water halogen, vitriol, sulphite, hyposulfite, thiosulphate, persulphate, nitrate, nitrite, chlorosulfonate, carbonate, supercarbonate, phosphoric acid salt, phosphite, metaphosphate, the pyrophosphate salt etc. one or more.Halogen comprises fluorine, chlorine, bromine and salt compounded of iodine, is one or more of oxymuriate, hypochlorite, chlorite, perchlorate, bromate, hypobromite, iodate, hypoiodite, hyperbromic acid salt, periodate.
Tensio-active agent described in the step (1) be the VB value less than 1 water-in-oil-type tensio-active agent, be selected from SP-60, SP-65, SP-80, SP-85, M-201, fatty acid monoglyceride, lipid acid two sweet esters, ethylene glycol monostearate, glycol ether monostearate, propyleneglycoles list dodecyl ester, polyisobutenyl maleic anhydride polyol ester, hydramine ester emulsifying agent and the succimide class emulsifying agent one or more.Relevant VB value notion please refer to " the A Study of Identifying Emulsion Type ofSurfactant--Volume Balance Value " that this patent people is published in the Journal of colloid andinterface science fourth phase in 2002.
The employed hydrocarbon component of step (1) is one or more of atmosphere 3rd side cut distillate, vacuum distillate, decompression slack wax, residual oil slack wax, deasphalted oil, vegetables oil, animal oil.Wherein vacuum distillate is vacuum 1st side cut distillate, second line of distillation distillate, subtracts three-way distillate, subtracts one or more mixture of the dewaxing of four line distillates or wax-containing distillate, can come from paraffinic base, intermediate base or naphthenic base crude; The decompression slack wax is vacuum 1st side cut distillate, second line of distillation distillate, subtracts three-way distillate, subtracts one or more slack waxs that obtain in the four line distillates, as being the second line of distillation slack wax, subtracting three-way slack wax, subtracting four line slack waxs and composition thereof; The residual oil slack wax is frivolous asphalt oil and/or heavy deasphalting slack wax; Deasphalted oil is frivolous asphalt oil and/or heavy deasphalted oil.Vegetables oil is one or more in soya-bean oil, peanut oil, rape seed oil, Viscotrol C, Oleum Helianthi, Oleum Cocois and the plam oil; Animal oil is one or more in butter, sheep oil and the lard.
Cosurfactant described in the step (1) is one or more in petroleum sodium sulfonate, calcium mahogany sulfonate, barium mahogany sulfonate, sodium stearate, sodium oleate, potassium stearate, potassium oleate, Yelkin TTS, phosphoric acid fat, fatty alcohol-polyoxyethylene ether (10), aliphatic acid polyethenoxy ether (15), alkylphenol polyoxyethylene (7), aliphatic amine polyoxyethylene ether (15), polyoxyethylene glycol (400), Yatall MA acid amides, sodium laurylsulfonate and the dodecyl alcohol acyl phosphoric acid ester.
In the step (2), used precipitation agent is for being selected from sodium hydroxide, potassium hydroxide, ammonia, volatile salt, salt of wormwood, yellow soda ash, sodium bicarbonate, bicarbonate of ammonia, urea, in hexamethylenetetramine and the ammonium citrate one or more, wherein the used precipitation agent of method one and method four is for being selected from sodium hydroxide, potassium hydroxide, ammonia, volatile salt, salt of wormwood, yellow soda ash, sodium bicarbonate, in the bicarbonate of ammonia one or more, mode with saturated or supersaturated aqueous solution adds, preferred ammonia, add with saturated ammoniacal liquor form, method three and method six used precipitation agents are urea, in hexamethylenetetramine and the ammonium citrate one or more.
In step (2) method one, method two, method four and the method five, the melt temperature of transition metal salt is 50~300 ℃, and preferred 50~200 ℃, in method three and the method six, the melt temperature of transition metal salt and precipitation agent is 50~300 ℃, preferred 50~200 ℃.In general the fusing point of two or more inorganic melts is all lower than the fusing point of itself, but the fusing point of some inorganic melts is very high, and its eutectic fusing point is still very high, and this just needs fusing assistant to reduce its fusing point.Fusing assistant is low mass molecule alcohol or water.A kind of or the mixture of low mass molecule alcohol foot methyl alcohol, ethanol, propyl alcohol and butanols.Water is distilled water or deionized water.Weight with the mixture of step (2) gained is benchmark, and the consumption of fusing assistant is 0~20wt%, is preferably 0.1~10wt%.
Step (1) gained mixture heating up to 50~300 ℃, is preferably melt temperature ± 20 ℃ that are heated to transition metal salt or transition metal salt and precipitation agent by preferred 50~200 ℃.
Wearing out described in the step (2) generally is to become under the glue temperature and pressure to wear out 0~30 hour, and the digestion time of method one the best is 3~24 hours, and the digestion time of method two the best is 1~4 hour, and the digestion time of method three the bests is 5~30 hours.
In the inventive method, step (2) reaction product aftertreatment is washed, and at first uses organic solvent ethanol or acetone, and washed product 0-3 time washes throw out Zhiyin ion weight concentration with water then less than 0.5%, wherein preferably adopts distilled water or deionized water.Throw out after the separation carries out oven dry in 5~24 hours under 80~110 ℃ of conditions.In the presence of air or inert gas (preferred nitrogen),, be warming up to 400~800 ℃ of roastings 5~20 hours then 200~300 ℃ of roastings 1~3 hour.Wherein the separation of mixture can be adopted the method for any separation solidliquid mixture of the prior art in the washing process, such as filtration, centrifugation, vacuum-evaporation, supercritical extraction etc.
The character of the transition metal oxide of the inventive method gained is as follows: median size 5~40nm, specific surface 30~110m
2/ g, pore volume 0.1~0.3ml/g, mean pore size 11~16nm.Surface-area among the present invention and pore structure are with U.S. ASAP2400 type low temperature liquid nitrogen absorption instrument, calculate by the BET method.Median size wherein is the mean diameter that obtains with the analysis of X-ray grating spectrum.
Transition metal oxide of the present invention can be used for fine ceramics, self cleaning enamel, piezoelectric, photoelectric material, magneticsubstance, catalyzer, catalyst base, coating, dyestuff, chemical sensor, fuel cell electrode material, hydrogen-storing material and ultraviolet screener etc.
The prepared nano transition metal oxides of the inventive method has the following advantages:
1, the inventive method is to utilize the character of the high interior phase dispersion system of oil bag melting salt, and transparent, stable, the super solubilising micelle of nanometer system that this system is made up of oil, tensio-active agent and melting salt wherein also can add cosurfactant.Because it is synthetic that precipitation of hydroxide that melting salt and precipitation agent form or gel are limited in carrying out in the micelle original position, thereby the increase of oxide diameter sizes, the narrow monodisperse status that is of particle size distribution range have been avoided.
2, adopt the transition metal fused salt in the inventive method, the productive rate height of nano-oxide, the purity height, and used tensio-active agent and hydrocarbon component consumption are little, cost is low.
3, outstanding feature is with high-temperature molten salt in the inventive method, rather than is that the liquid phase method of solvent prepares nano transition metal oxides with water.
4, the inventive method technology is simple, can carry out industrial production in enormous quantities.
Description of drawings
Fig. 1 is the transmission electron microscope picture of the nano-nickel oxide of enforcement 10 gained.
Embodiment
Among the present invention, the preferred preparation method of nano transition metal oxyhydroxide micelle system is as follows.
Method one:
A, under normal pressure, transition metal salt is heated to 50~120 ℃ of fusions, slowly join in 30~120 ℃ the mixture of hydrocarbon component, tensio-active agent and cosurfactant, mixing time is 1 minute~60 minutes;
B, directly adding precipitation agent reaction in above-mentioned mixture; 70~120 ℃ of control reaction temperature wear out then, and digestion time is 3~24 hours; Wherein used precipitation agent is one or more in sodium hydroxide, potassium hydroxide, volatile salt, salt of wormwood, yellow soda ash, sodium bicarbonate, bicarbonate of ammonia and the ammonia.This precipitation agent generally adds with the form of the aqueous solution, preferably adopts saturated or oversaturated aqueous solution form adding, preferably adopts ammonia, and adds with saturated ammoniacal liquor form.
Method two:
A, transition metal salt is heated to fusion, be generally 50~300 ℃, slowly join in 50~300 ℃ the mixture of hydrocarbon component, tensio-active agent and cosurfactant, mixing time is 1 minute~60 minutes, be preferably 5 minutes~30 minutes, be preferably 10 minutes~20 minutes, make it form evenly super solubilising micelle;
In B, the mixture, be mixed to and form evenly super solubilising micelle the slow adding of fused transition metal salt 50~300 ℃ of steps (1) gained; In confined conditions, below the ammonia critical temperature, be generally the critical temperature of 30~ammonia, add precipitation agent liquefied ammonia, or in confined conditions, feed ammonia under 30~300 ℃ of temperature and carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle system;
Method three:
A, precipitation agent and all or part of transition metal salt mixed after, be heated to 50~120 ℃ of fusions, slowly join then in 30~120 ℃ the described mixture of step (1), be mixed to and form evenly super solubilising micelle, again remainder fused transition metal salt is added in the said mixture;
B, under airtight condition, the colloid that steps A is obtained carries out the precipitation from homogeneous solution reaction under 70~200 ℃, the reaction times is 4~8 hours, aging 0~30 hour then, obtains transition metal hydroxide micelle system; Wherein used precipitation agent is one or more in urea, hexamethylenetetramine and the ammonium citrate.
Method four:
A, under normal pressure, transition metal salt is heated to 50~120 ℃ of fusions, slowly join in 30~120 ℃ the mixture of hydrocarbon component, tensio-active agent and cosurfactant, mixing time is 1 minute~60 minutes; Again fused low melting point transition salt is added in the above-mentioned micelle system, mixes;
B, directly adding precipitation agent reaction in above-mentioned mixture; 70~120 ℃ of control reaction temperature wear out then, and digestion time is 3~24 hours; Wherein used low melting point transition salt is the inorganic transition metal salt of fusing point in-100~50 ℃ of scopes; Used precipitation agent is one or more in sodium hydroxide, potassium hydroxide, volatile salt, salt of wormwood, yellow soda ash, sodium bicarbonate, bicarbonate of ammonia and the ammonia.This precipitation agent generally adds with the form of the aqueous solution, preferably adopts saturated or oversaturated aqueous solution form adding, preferably adopts ammonia, and adds with saturated ammoniacal liquor form.
Method five:
A, transition metal salt is heated to fusion, be generally 50~300 ℃, slowly join in 50~300 ℃ the mixture of hydrocarbon component, tensio-active agent and cosurfactant, mixing time is 1 minute~60 minutes, be preferably 5 minutes~30 minutes, be preferably 10 minutes~20 minutes, make it form evenly super solubilising micelle; Again fused low melting point transition salt is added in the above-mentioned micelle system, mixes;
In B, the mixture, be mixed to and form evenly super solubilising micelle the slow adding of fused transition metal salt 50~300 ℃ of steps (1) gained; In confined conditions, below the ammonia critical temperature, be generally the critical temperature of 50~ammonia, add precipitation agent liquefied ammonia, or in confined conditions, feed ammonia under 30~300 ℃ of temperature and carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle system; Wherein used low melting point transition salt is the inorganic transition metal salt of fusing point in-100~50 ℃ of scopes.
Method six:
A, precipitation agent and transition metal salt mixed after, be heated to 50~120 ℃ of fusions, slowly join then in 30~120 ℃ the described mixture of step (1), be mixed to and form evenly super solubilising micelle; Again fused low melting point transition salt is added in the above-mentioned micelle system, mixes;
B, under airtight condition, the colloid that steps A is obtained carries out the precipitation from homogeneous solution reaction under 70~200 ℃, the reaction times is 4~8 hours, aging 0~30 hour then, obtains transition metal hydroxide micelle system; Wherein used low melting point transition salt is the inorganic transition metal salt of fusing point in-100~50 ℃ of scopes, and used precipitation agent is one or more in urea, hexamethylenetetramine and the ammonium citrate.
The mixture of the melts of described transition metal salt or transition metal salt and precipitation agent can once slowly be added in the described mixture of step (1), also can slowly be added to several times in the described mixture of step (1).When transition metal salt is multiple, can mixed melting, also can distinguish fusion, add or mix the back respectively and add, can once add, also can add several times.
The present invention is further described below in conjunction with embodiment.
Used hydrocarbon component picks up from the general petrochemical works, Lanzhou in the embodiment of the invention, and its character sees Table 1.
The character of table 1 hydrocarbon component
Condensation point, ℃ | Oleaginousness, wt% | Viscosity (100 ℃), mm 2/s | Penetration degree (25 ℃), 1/10mm | |
The atmosphere 3rd side cut distillate | 5 | 90 | 2.01 | / |
The vacuum 1st side cut distillate | 30 | 80 | 4.98 | / |
The second line of distillation distillate | 35 | 75 | 5.02 | / |
Subtract three-way distillate | 37 | 68 | 5.55 | / |
Subtract four line distillates | 42 | 56 | 8.58 | 46 |
The second line of distillation slack wax | 50 | 7.5 | 4.82 | 20 |
Subtract three-way slack wax | 53 | 8.5 | 5.02 | 19 |
Subtract four line slack waxs | 56.5 | 22 | 6.08 | 25 |
The residual oil slack wax | 69 | 32.5 | 19.3 | 40 |
Frivolous asphalt oil | 38 | 72 | 8.82 | / |
Heavy deasphalted oil | 40 | 69 | 12.1 | 65 |
Embodiment 1
100g atmosphere 3rd side cut pressed oil, 50gSP-80 are mixed, and 120 ℃ of heating for dissolving mix; The 590g Gerhardite is heated to 120 ℃ of fusions, slowly adds in the said mixture, mix forming evenly super solubilising colloid in 10 minutes.200g sodium hydroxide is added 60g water heating for dissolving, add in the super solubilising colloid that forms, mix.With washing with alcohol once, be washed with distilled water to SODIUMNITRATE then less than 0.5w%, centrifugation.110 ℃ of oven dry 18 hours, 400 ℃ of roastings 5 hours, i.e. present embodiment nano cupric oxide, its character is as follows: median size 19nm, BET specific surface 73m
2/ g, pore volume (ml/g) 0.193, mean pore size () 159.
Embodiment 2
With 67g subtract four line oil, 10g polyisobutenyl toxilic acid glyceryl ester mixes 100 ℃ of heating for dissolving; 800g six nitric hydrate iron are heated to 120 ℃ of fusions, slowly add in the said mixture, mix forming evenly super solubilising colloid in 20 minutes.123g liquefied ammonia slowly adds in the said mixture, closed reactor, and 110 ℃ were reacted 2 hours.Closed reactor was 200 ℃ of reactions 4 hours, aging 10 hours.Be washed with distilled water to the ammonium nitrate weight concentration then less than 0.5wt%, centrifugation.100 ℃ of oven dry 10 hours, 500 ℃ of roastings 8 hours, i.e. the nano-sized iron oxide of present embodiment, its character is as follows: median size 36nm, BET specific surface 69m2/g, pore volume (ml/g) 0.21, mean pore size () 129.
Embodiment 3
300g second line of distillation oil, 30g polyisobutenyl toxilic acid triethanolamine ester are mixed 100 ℃ of heating for dissolving; 500g manganese nitrate hexahydrate, 170g urea are mixed and heated to 120 ℃ of fusions, slowly add in the said mixture, mix forming evenly super solubilising colloid in 20 minutes.Closed reactor, 200 ℃ of reactions 4 hours, wearing out obtained nanometer manganous hydroxide gel in 10 hours.Be washed with distilled water to the ammonium nitrate weight concentration then less than 0.5wt%, centrifugation.100 ℃ of oven dry 10 hours, 500 ℃ of roastings 8 hours, i.e. present embodiment nano manganese oxide, its character is as follows: median size 27nm, BET specific surface 82m
2/ g, pore volume (ml/g) 0.24, mean pore size () 131.
Embodiment 4
80g is subtracted three-way pressed oil and the mixing of 22g polyisobutenyl toxilic acid glycol ether ester, and 50 ℃ of heating for dissolving mix; 400g titanium tetrachloride, 192g ethanol and 155g water are heated to a ℃ fusion, are added to then in the said mixture, mix forming evenly super solubilising colloid in 30 minutes.151g liquefied ammonia slowly adds in the said mixture, closed reactor, and 110 ℃ were reacted 2 hours.Reactant through distilled water wash to weight ammonium chloride concentration less than 0.5%, obtain the nano titanium oxide gel.100 ℃ of oven dry 20 hours, 550 ℃ of roastings 8 hours, i.e. present embodiment nano titanium oxide, its character is as follows: median size 13nm, BET specific surface 98m
2/ g, pore volume (ml/g) 0.189, mean pore size () 141.
Embodiment 5
66g first vacuum side stream, 5g polyisobutenyl toxilic acid glycol ether ester are mixed, and 120 ℃ of heating for dissolving mix; 420g eight hydration zirconium oxychlorides are heated to 120 ℃ of fusions, slowly add in the said mixture, mix forming evenly super solubilising colloid in 10 minutes.With dissolving in the 300g potassium hydroxide adding 209g water, add in the super solubilising colloid that forms, mix.Products therefrom with washing with alcohol once is washed with distilled water to SODIUMNITRATE less than 0.5w%, centrifugation then.110 ℃ of oven dry 18 hours, 400 ℃ of roastings 5 hours, i.e. the nano zircite of present embodiment, its character is as follows: median size 21nm, BET specific surface 88m
2/ g, pore volume 0.189ml/g, mean pore size () 141.
Embodiment 6
70g is subtracted three-way pressed oil, 60g peanut oil and 30g SP-80,20g T-154 and 10g OP-4 mix, 110 ℃ of heating for dissolving mix; The 670g Cobaltous nitrate hexahydrate is heated to 110 ℃ of fusions, is added to then in the said mixture, mix forming evenly super solubilising colloid in 30 minutes.Closed reactor slowly adds in the said mixture at room temperature 140g liquefied ammonia, and 110 ℃ were reacted 2 hours.Reactant through distilled water wash to the ammonium nitrate weight concentration less than 0.5%, centrifugation.110 ℃ of oven dry 18 hours, 400 ℃ of roastings 5 hours, i.e. the nano oxidation of present embodiment is bored, and its character is as follows: median size 29nm, BET specific surface 96m2/g, pore volume (ml/g) 0.18, mean pore size () 128.
Embodiment 7
10g second line of distillation slack wax, 20g are subtracted four line slack waxs, 10g heavy deasphalted oil, 15g T-155 and 8g calcium mahogany sulfonate mix, 80 ℃ of heating for dissolving mix; 350g molybdenum pentachloride, 147g ethanol, 200g urea and 240g water are heated to 80 ℃ of fusions, are added to then in the said mixture, mix forming evenly super solubilising colloid in 30 minutes.Closed reactor, 110 ℃ were reacted 2 hours.Reactant through distilled water wash to weight ammonium chloride concentration less than 0.5%, centrifugation.110 ℃ of oven dry 18 hours, 400 ℃ of roastings 5 hours, i.e. the nano oxidized molybdenum of present embodiment, its character is as follows: median size 14nm, BET specific surface 66m2/g, pore volume (ml/g) 0.17, mean pore size () 158.
Embodiment 8
The frivolous asphalt oil of 100g, 30g are subtracted three-way slack wax, 2g T-155 and 30g polyisobutenyl toxilic acid triethanolamine ester to mix 80 ℃ of heating for dissolving; 310g yttrium trichloride, 192g ethanol, 150g urea and 186g water are heated to 80 ℃ of fusions, are added to then in the said mixture, mix forming evenly super solubilising colloid in 30 minutes.Closed reactor, 120 ℃ of reactions 6 hours, aging 10 hours, resultant of reaction through distilled water wash to weight ammonium chloride concentration less than 0.5%, centrifugation.100 ℃ of oven dry 20 hours, 600 ℃ of roastings 5 hours, i.e. the nano yttrium oxide of present embodiment, its character is as follows: median size 11nm, BET specific surface 80m
2/ g, pore volume (ml/g) 0.18, mean pore size () 125.
Embodiment 9
65g is subtracted four lines oil and 12g polyisobutenyl toxilic acid glyceryl ester mixes 120 ℃ of heating for dissolving; 375g Silver Nitrate and 104g water are heated to 120 ℃ of fusions, slowly add in the said mixture, mix forming evenly super solubilising colloid in 20 minutes.The 154g titanous chloride splashes in the above-mentioned micelle, mixes.With dissolving in the 210g sodium hydroxide adding 80g water, add in the super solubilising colloid that forms, mix.Reaction product through distilled water wash to SODIUMNITRATE less than 0.5%, centrifugation.110 ℃ of oven dry 18 hours, 400 ℃ of roastings 5 hours, i.e. the nano-titanium argentine composite oxides of present embodiment, its character is as follows: median size 15nm, BET specific surface 65m
2/ g, pore volume (ml/g) 0.21, mean pore size () 145.
Embodiment 10
10g residual oil slack wax, 34g Oleum Cocois, 20g sheep oil, 15g OP-4,1g SP-40 and 10g polyisobutenyl toxilic acid triethanolamine ester are mixed 100 ℃ of heating for dissolving; The 450g Nickelous nitrate hexahydrate is heated to 120 ℃ of fusions, slowly adds in the said mixture, mix forming evenly super solubilising colloid in 20 minutes.The 280g titanium tetrachloride splashes in the above-mentioned micelle, mixes.Closed reactor feeds 180g liquefied ammonia reaction 2 hours at 100 ℃, aging 10 hours, reaction product through distilled water wash to weight ammonium chloride concentration less than 0.5%, centrifugation.110 ℃ of oven dry 18 hours, 400 ℃ of roastings 5 hours, i.e. the nano-nickel oxide of present embodiment, its character is as follows: median size 35nm, BET specific surface 90m
2/ g, pore volume (ml/g) 0.20, mean pore size () 166.
Embodiment 11
90g is subtracted three-way pressed oil, 10g SP-40 and 20g SP-80 to mix 100 ℃ of heating for dissolving; 500g zinc nitrate hexahydrate and 180g urea are heated to 120 ℃ of fusions, slowly add in the said mixture, mix forming evenly super solubilising colloid in 20 minutes.The 200g titanium tetrachloride splashes in the above-mentioned micelle, mixes.Closed reactor, 140 ℃ of reactions 6 hours, aging 10 hours, reactant through distilled water wash to weight ammonium chloride concentration less than 0.5%, centrifugation.110 ℃ of oven dry 8 hours, 400 ℃ of roastings 5 hours, i.e. the nanometer titanium zinc composite oxide of present embodiment, its character is as follows: median size 18nm, BET specific surface 75m
2/ g, pore volume (ml/g) 0.19, mean pore size () 132.
Embodiment 12
70g is subtracted four line oil, 5gT-154,20g M-201 and 15g polyisobutenyl toxilic acid glycol ether ester to mix 100 ℃ of heating for dissolving; 342g vanadium tetrachloride, 160g ethanol, 246g urea and 142g water are heated to 80 ℃ of fusions, are added to then in the said mixture, mix forming evenly super solubilising colloid in 30 minutes.Closed reactor, 160 ℃ of reactions 2 hours, aging 3 hours, reactant through distilled water wash to weight ammonium chloride concentration less than 0.5%, centrifugation.110 ℃ of oven dry 18 hours, 800 ℃ of roastings 5 hours, i.e. the vanadium oxide nanoparticle of present embodiment, its character is as follows: median size 23nm, BET specific surface 70m
2/ g, pore volume (ml/g) 0.22, mean pore size () 123.
Embodiment 13
50g subtracts third fractional oil and 15g polyisobutenyl toxilic acid triethanolamine ester mixes, and is heated to 250 ℃ of dissolvings, mixes; 606g gold trichloride and 120g water are mixed and heated to 250 ℃ of fusions, slowly add in the oil mixture, are mixed to form evenly super solubilising micelle; Under 250 ℃ of temperature, feed the 209g ammonia and carry out neutralization reaction, obtain nanometer auric hydroxide precipitation.Throw out is washed till ammonium chloride concentration less than 0.5wt% with distilled water, 100 ℃ of oven dry 24 hours, and 650 ℃ of roastings 15 hours, i.e. the nano oxidized gold of present embodiment, tool character is as follows: median size 15nm, BET specific surface 90m
2/ g, pore volume (ml/g) 0.169, mean pore size () 130.Embodiment 14
105g second line of distillation oil and 25g polyisobutenyl toxilic acid monoethanolamine ester mix, and are heated to 100 ℃ of dissolvings, mix; 350g zinc nitrate hexahydrate and 300g six nitric hydrate copper are mixed and heated to 100 ℃ of fusions, slowly add in the oil mixture, are mixed to form evenly super solubilising micelle; Under 100 ℃ of temperature, feed the 220g ammonia and carry out neutralization reaction, obtain nanometer zinc hydroxide and nanometer copper hydroxide mixed sediment.Throw out is washed till ammonium nitrate concn less than 0.5wt% with distilled water, 100 ℃ of oven dry 24 hours, and 650 ℃ of roastings 15 hours, i.e. the nanometer copper zinc oxide of present embodiment, its character is as follows: median size 35nm, BET specific surface 62m
2/ g, pore volume (ml/g) 0.22, mean pore size () 130.
Embodiment 15
50g subtracts third fractional oil and 20g polyisobutenyl toxilic acid diethanolamine ester mixes, and is heated to 80 ℃ of dissolvings, mixes; 750g four nitric hydrate cadmiums are mixed and heated to 80 ℃ of fusions, slowly add in the oil mixture, are mixed to form evenly super solubilising micelle; Under 150 ℃ of temperature, feed the 180g ammonia and carry out neutralization reaction, obtain nanometer cadmium hydroxide precipitation.Throw out is washed till ammonium chloride concentration less than 0.5wt% with distilled water, 100 ℃ of oven dry 24 hours, and 650 ℃ of roastings 15 hours, i.e. the nano oxidized cadmium of present embodiment, its character is as follows: median size 13nm, BET specific surface 98m
2/ g, pore volume (ml/g) 0.189, mean pore size () 141.
Claims (24)
1, a kind of preparation method of nano transition metal oxides may further comprise the steps:
(1) hydrocarbon component, VB value are mixed less than 1 tensio-active agent and cosurfactant;
(2) nano transition metal oxyhydroxide micelle is made by following at least a method:
Method one: the fused transition metal salt slowly joins in the mixture of step (1) gained, is mixed to form evenly super solubilising micelle; Add precipitation agent then, under 50~120 ℃ of temperature, carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method two: the fused transition metal salt is slowly added in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle; In confined conditions, below the ammonia critical temperature, in above-mentioned micelle system, add precipitation agent liquefied ammonia and carry out neutralization reaction, or in confined conditions, at 30~300 ℃, in above-mentioned micelle system, feed ammonia and carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method three: use precipitation agent and all or part of transition metal salt to mix the post-heating fusion, slowly join in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle, the remainder transition metal salt slowly is added in the above-mentioned micelle system again; Under airtight condition, resulting micelle system is carried out precipitation from homogeneous solution under 70~200 ℃ of temperature, in 4~8 hours reaction times, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
(3) with the nano transition metal oxyhydroxide of step (2) gained,, obtain nano grade transition metal oxide compound of the present invention then through washing, oven dry and roasting;
Wherein water adds with crystal water and/or free-water form in step (1) and/or step (2);
Weight with step (2) gained mixture is benchmark, the consumption of transition metal salt (butt), precipitation agent and water is 60wt%~96wt%, the water yield is the 100wt%~350wt% as the theoretical water requirement of reaction water, the consumption of precipitation agent is 100~300wt% of theoretical requirement, and the consumption of tensio-active agent is 0.1wt%-8wt%; The consumption of hydrocarbon component is 3wt%~30wt%; The consumption of cosurfactant is 0~2.0wt%.
2, preparation method according to claim 1 is characterized in that transition metal salt used in the step (2) is two or more, and when adopting a kind of low melting point transition metal salt at least, adopts following at least a method to make:
Method four: the fused transition metal salt slowly joins in the mixture of step (1) gained, is mixed to form evenly super solubilising micelle; Again fused low melting point transition metal salt is added in the above-mentioned micelle system, mixes, add precipitation agent then, under 50~120 ℃ of temperature, carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method five: the fused transition metal salt is slowly added in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle; Again fused low melting point transition metal salt is added in the above-mentioned micelle system, mixes; In confined conditions, below the ammonia critical temperature, in above-mentioned micelle system, add precipitation agent liquefied ammonia and carry out neutralization reaction, or in confined conditions, at 30 ℃~300 ℃, in above-mentioned micelle system, feed ammonia and carry out neutralization reaction, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Method six: use precipitation agent and transition metal salt to mix the post-heating fusion, slowly join in the mixture of step (1) gained, be mixed to and form evenly super solubilising micelle; Again fused low melting point transition metal salt is added in the above-mentioned micelle system, mix, under airtight condition, resulting micelle system is carried out precipitation from homogeneous solution be neutralized into glue under 70~200 ℃ of temperature, gelation time 4~8 hours, aging 0~30 hour then, obtain nano transition metal oxyhydroxide micelle;
Wherein, the melting range of described low melting point transition metal salt is at-100 ℃~50 ℃.
3, method according to claim 1 and 2, it is characterized in that the weight with the mixture of step (2) gained is benchmark, the consumption of transition metal salt (butt), precipitation agent and water is 85wt%~96wt%, the water yield is that the consumption of tensio-active agent is 0.5wt%-5wt% as the 100wt%~300w% of the theoretical water requirement of reaction water; The consumption of hydrocarbon component is 3wt%~15wt%; The consumption of cosurfactant is 0~1.0wt%.
4, method according to claim 1 and 2 is characterized in that the weight with the mixture of step (2) gained is benchmark, and the water yield is the 100wt%~200wt% as the theoretical water requirement of reaction water, and the consumption of tensio-active agent is 0.8wt%-3wt%; The consumption of hydrocarbon component is 4wt%~8wt%; The consumption of cosurfactant is 0~0.5wt%.
5, preparation method according to claim 1 and 2, it is characterized in that described hydromining adds with following one or more modes: a, in step (1), add entry, b, in step (2), adopt the form of the inorganic salt contain crystal water to add, c, in the melts melting process, add entry, d, form with the mixture of step (1) gained and to add in the even colloidal process or after forming even colloid, to add.
6, preparation method according to claim 1 and 2 is characterized in that described water, and method one and method four are to adopt the precipitation agent aqueous solution, and contain the inorganic salt of crystal water and/or add entry in the melts melting process; Method two, method three, method five and method six are to adopt to contain the inorganic salt of crystal water and/or add entry in the melts melting process.
7, method according to claim 1 and 2 is characterized in that described transition metal is one or more in the transition metal in the 4th and five cycles.
8, method according to claim 1 and 2 is characterized in that described transition metal is one or more in titanium, iron, nickel, manganese, zirconium, copper, vanadium, chromium, cadmium, gold, ruthenium, rhodium, tungsten, palladium, silver, platinum, yttrium, molybdenum, zinc and the cobalt.
9, method according to claim 1 and 2 is characterized in that described transition metal salt is to contain crystal water or do not contain in crystal water halogen, vitriol, sulphite, hyposulfite, thiosulphate, persulphate, nitrate, nitrite, chlorosulfonate, carbonate, supercarbonate, phosphoric acid salt, phosphite, metaphosphate, the pyrophosphate salt etc. one or more; Wherein halogen is one or more of oxymuriate, hypochlorite, chlorite, perchlorate, bromate, hypobromite, iodate, hypoiodite, hyperbromic acid salt, periodate.
10, method according to claim 1 and 2 is characterized in that the tensio-active agent described in the step (1) is selected from one or more in SP-40, SP-60, SP-65, SP-80, SP-85, M-201, fatty acid monoglyceride, two sweet esters, ethylene glycol monostearate, glycol ether monostearate, propyleneglycoles list dodecyl ester, polyisobutenyl maleic anhydride polyol ester, hydramine ester emulsifying agent and the succimide class emulsifying agent.
11, method according to claim 1 and 2 is characterized in that the employed hydrocarbon component of step (1) is one or more of atmosphere 3rd side cut distillate, vacuum distillate, decompression slack wax, residual oil slack wax, deasphalted oil, vegetables oil, animal oil.
12, method according to claim 11 is characterized in that described vacuum distillate is vacuum 1st side cut distillate, second line of distillation distillate, subtracts three-way distillate, subtracts one or more mixture of the dewaxing of four line distillates or wax-containing distillate; The decompression slack wax is vacuum 1st side cut distillate, second line of distillation distillate, subtracts three-way distillate, subtracts one or more slack waxs that obtain in the four line distillates; The residual oil slack wax is frivolous asphalt oil and/or heavy deasphalting slack wax; Deasphalted oil is frivolous asphalt oil and/or heavy deasphalted oil; Vegetables oil is one or more in soya-bean oil, peanut oil, rape seed oil, Viscotrol C, Oleum Helianthi, Oleum Cocois and the plam oil; Animal oil is one or more in butter, sheep oil and the lard.
13, method according to claim 1 and 2 is characterized in that the cosurfactant described in the step (1) is one or more in petroleum sodium sulfonate, calcium mahogany sulfonate, barium mahogany sulfonate, sodium stearate, sodium oleate, potassium stearate, potassium oleate, Yelkin TTS, phosphoric acid fat, fatty alcohol-polyoxyethylene ether (10), aliphatic acid polyethenoxy ether (15), alkylphenol polyoxyethylene (7), aliphatic amine polyoxyethylene ether (15), polyoxyethylene glycol (400), Yatall MA acid amides, sodium laurylsulfonate and the dodecyl alcohol acyl phosphoric acid ester.
14, method according to claim 1 and 2 is characterized in that the precipitation agent described in the step (2) is to be selected from sodium hydroxide, potassium hydroxide, ammonia, volatile salt, salt of wormwood, yellow soda ash, sodium bicarbonate, bicarbonate of ammonia, urea, hexamethylenetetramine and the ammonium citrate one or more.
15, method according to claim 1 and 2, it is characterized in that in the step (2), method one and method four used precipitation agents are to be selected from sodium hydroxide, potassium hydroxide, ammonia, volatile salt, salt of wormwood, yellow soda ash, sodium bicarbonate, the bicarbonate of ammonia one or more, mode with saturated or supersaturated aqueous solution adds, and method three and method six used precipitation agents are one or more in urea, hexamethylenetetramine and the ammonium citrate.
16, method according to claim 1 and 2 is characterized in that in the step (2), and method one and method four used precipitation agents are ammonia, adds with saturated ammoniacal liquor form.
17, preparation method according to claim 1 and 2 is characterized in that the melt temperature of transition metal salt in the step (2) is 50~300 ℃, and the melt temperature of transition metal salt and precipitation agent is 50~300 ℃.
18, preparation method according to claim 1 and 2 is characterized in that step (1) gained mixture heating up to 50~300 ℃.
19, preparation method according to claim 1 and 2 is characterized in that step (1) gained mixture heating up is to melt temperature ± 20 of transition metal salt or transition metal salt and precipitation agent ℃.
20, method according to claim 1 and 2 is characterized in that adding fusing assistant in the transition metal salt melting process, and described fusing assistant is low mass molecule alcohol or water, and wherein low mass molecule alcohol is a kind of or mixture of methyl alcohol, ethanol, propyl alcohol and butanols; Weight with the mixture of step (2) gained is benchmark, and the consumption of fusing assistant is 0~20wt%.
21, method according to claim 1 and 2, it is characterized in that the digestion time described in the step (2) is specific as follows: the digestion time of method one and method four is 3~24 hours, the digestion time of method two and method five is 1~4 hour, and the digestion time of method three and method six is 5~30 hours.
22, method according to claim 1 and 2 is characterized in that the washing described in the step (3), at first uses organic solvent washing product 0-3 time, washes throw out Zhiyin ion weight concentration then with water less than 0.5%; Described drying condition: under 80~110 ℃ of conditions, dried 5~24 hours.
23, method according to claim 1 and 2 is characterized in that the described roasting condition of step (3): 200~300 ℃ of roastings 1~3 hour, be warming up to 400~800 ℃ of roastings 5~20 hours then.
24, method according to claim 1 and 2 is characterized in that the character of nano transition metal oxides of gained is as follows: median size 5~40nm, specific surface 30~110m
2/ g, pore volume 0.1~0.3ml/g, mean pore size 11~16nm.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CNB2005100464789A CN100345762C (en) | 2005-05-18 | 2005-05-18 | Nano transitional metallic oxide preparation method |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CNB2005100464789A CN100345762C (en) | 2005-05-18 | 2005-05-18 | Nano transitional metallic oxide preparation method |
Publications (2)
Publication Number | Publication Date |
---|---|
CN1865150A true CN1865150A (en) | 2006-11-22 |
CN100345762C CN100345762C (en) | 2007-10-31 |
Family
ID=37424323
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CNB2005100464789A Active CN100345762C (en) | 2005-05-18 | 2005-05-18 | Nano transitional metallic oxide preparation method |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN100345762C (en) |
Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101948140A (en) * | 2010-09-20 | 2011-01-19 | 上海理工大学 | Method for preparing Fe2O3 and Fe3O4 nano materials by taking F2<2+> salt as raw material |
CN103097286A (en) * | 2011-04-28 | 2013-05-08 | M技术株式会社 | Method for producing oxide/hydroxide |
CN106340396A (en) * | 2016-11-02 | 2017-01-18 | 信阳师范学院 | Method for preparing CdCo2S4 nano-structured super-capacitor electrode material using foam nickel as the substrate |
CN108295841A (en) * | 2018-01-31 | 2018-07-20 | 中国科学院上海高等研究院 | A kind of oxidation of formaldehyde catalyst and its preparation method and application |
CN112758996A (en) * | 2020-12-14 | 2021-05-07 | 清华大学 | Bifunctional oxygen electrocatalyst and preparation and application thereof |
Family Cites Families (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN1163416C (en) * | 1994-07-02 | 2004-08-25 | 雷慧绪 | Method for producing cobalt oxide nickel oxide powder for electronic industry |
CN1071712C (en) * | 1997-03-06 | 2001-09-26 | 西北大学 | Method for preparing nanometre-grade zinc oxide |
CN1141254C (en) * | 2001-08-27 | 2004-03-10 | 清华大学 | Process for prepairng granularity controllable nm-class zirconium oxide |
-
2005
- 2005-05-18 CN CNB2005100464789A patent/CN100345762C/en active Active
Cited By (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101948140A (en) * | 2010-09-20 | 2011-01-19 | 上海理工大学 | Method for preparing Fe2O3 and Fe3O4 nano materials by taking F2<2+> salt as raw material |
CN101948140B (en) * | 2010-09-20 | 2013-05-29 | 上海理工大学 | Method for preparing Fe2O3 and Fe3O4 nano materials by taking F2<2+> salt as raw material |
CN103097286A (en) * | 2011-04-28 | 2013-05-08 | M技术株式会社 | Method for producing oxide/hydroxide |
US9127331B2 (en) | 2011-04-28 | 2015-09-08 | M. Technique Co., Ltd. | Method for producing oxide/hydroxide |
CN103097286B (en) * | 2011-04-28 | 2016-04-27 | M技术株式会社 | The manufacture method of oxide hydroxide |
CN106340396A (en) * | 2016-11-02 | 2017-01-18 | 信阳师范学院 | Method for preparing CdCo2S4 nano-structured super-capacitor electrode material using foam nickel as the substrate |
CN106340396B (en) * | 2016-11-02 | 2018-03-09 | 信阳师范学院 | A kind of nickel foam is the CdCo of substrate2S4The preparation method of nanostructured electrode material for super capacitor |
CN108295841A (en) * | 2018-01-31 | 2018-07-20 | 中国科学院上海高等研究院 | A kind of oxidation of formaldehyde catalyst and its preparation method and application |
CN108295841B (en) * | 2018-01-31 | 2021-03-12 | 中国科学院上海高等研究院 | Formaldehyde oxidation catalyst and preparation method and application thereof |
CN112758996A (en) * | 2020-12-14 | 2021-05-07 | 清华大学 | Bifunctional oxygen electrocatalyst and preparation and application thereof |
Also Published As
Publication number | Publication date |
---|---|
CN100345762C (en) | 2007-10-31 |
Similar Documents
Publication | Publication Date | Title |
---|---|---|
Thaweesak et al. | Two-dimensional g-C3N4/Ca2Nb2TaO10 nanosheet composites for efficient visible light photocatalytic hydrogen evolution | |
Kumar et al. | CuO/ZnO nanorods: An affordable efficient pn heterojunction and morphology dependent photocatalytic activity against organic contaminants | |
JP6722580B2 (en) | Photocatalyst and method for producing the same | |
CN1120045C (en) | Cds photocatalyst for producing hydrogen, its producing process and process for producing hydrogen using the same catalyst | |
CN100345762C (en) | Nano transitional metallic oxide preparation method | |
CN1791554A (en) | Metal oxide solid solution, preparation and use thereof | |
CN112495444B (en) | TiO2 2 Preparation method and application of @ HKUST-1 composite photocatalyst | |
CN101897061A (en) | Homogeneous nanoparticle core doping of cathode material precursors | |
CN107597109A (en) | Load type gold catalyst of nano-metal-oxide doping and preparation method and application | |
CN102698785A (en) | Preparation method of diatomite-loaded nitrogen-doped nanometer TiO2 photocatalysis material | |
US20220333011A1 (en) | Process for preparing multicolor, fluorescent carbon quantum dot nanoparticles from coal under mild oxidation conditions | |
CN1016143B (en) | Catalyst and catalyst precusor containing vanadium and antimony | |
CN1803272A (en) | Air bubble liquid membrane method for producing nanometer granule material | |
US20240246063A1 (en) | Process for producing composite material | |
CN106044835A (en) | Preparation method of nanoscale spherical yttrium oxide powder | |
CN102531037A (en) | Chemical preparation method of nanoscale zinc oxide powder | |
CN100434165C (en) | Method for preparing visible light catalyst of Nano crystal BiVO4 in high activity through ultrasound chemistry | |
Saini et al. | Visible light induced α-amino acid synthesis from carbon dioxide using nanostructured ZnO/CuO heterojunction photocatalyst | |
Marfur et al. | A Review on Recent Progression of Modifications on Titania Morphology and its Photocatalytic Performance. | |
CN102631937B (en) | Synthesis method of supported silver iodide nanoparticle visible light photocatalyst | |
CN105498779A (en) | Preparation method of nano copper based catalyst for CO2 hydrogenation for producing methanol | |
Shokrgozar et al. | Synthesis of Ni-Co-CNT nanocomposite and evaluation of its photocatalytic dye (Reactive Red 120) degradation ability using response surface methodology | |
CN1031864C (en) | Hydrogention catalyst and production process thereof | |
CN114130415A (en) | Preparation method of high photocatalytic phosphorus-doped graphite-phase carbon nitride/bismuth tungstate heterojunction | |
Shu et al. | Highly efficient near-infrared light photocatalytic hydrogen evolution over MoS 2 supported Ta 2 O 5 combined with an up-conversion luminescence agent (β-Tm 3+, Yb 3+: NaYF 4/MoS 2–Ta 2 O 5 nanocomposite) |
Legal Events
Date | Code | Title | Description |
---|---|---|---|
C06 | Publication | ||
PB01 | Publication | ||
C10 | Entry into substantive examination | ||
SE01 | Entry into force of request for substantive examination | ||
C14 | Grant of patent or utility model | ||
GR01 | Patent grant |