WO2012145911A1 - 一种制备石墨烯的方法 - Google Patents

一种制备石墨烯的方法 Download PDF

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WO2012145911A1
WO2012145911A1 PCT/CN2011/073458 CN2011073458W WO2012145911A1 WO 2012145911 A1 WO2012145911 A1 WO 2012145911A1 CN 2011073458 W CN2011073458 W CN 2011073458W WO 2012145911 A1 WO2012145911 A1 WO 2012145911A1
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acid
graphite
graphene
product
hour
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PCT/CN2011/073458
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English (en)
French (fr)
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刘兆平
周旭峰
秦志鸿
唐长林
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中国科学院宁波材料技术与工程研究所
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Priority to PCT/CN2011/073458 priority Critical patent/WO2012145911A1/zh
Priority to US13/577,027 priority patent/US9162894B2/en
Publication of WO2012145911A1 publication Critical patent/WO2012145911A1/zh

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    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01BNON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
    • C01B32/00Carbon; Compounds thereof
    • C01B32/15Nano-sized carbon materials
    • C01B32/182Graphene
    • C01B32/184Preparation
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B82NANOTECHNOLOGY
    • B82YSPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
    • B82Y30/00Nanotechnology for materials or surface science, e.g. nanocomposites
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B82NANOTECHNOLOGY
    • B82YSPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
    • B82Y40/00Manufacture or treatment of nanostructures
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10TECHNICAL SUBJECTS COVERED BY FORMER USPC
    • Y10STECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y10S977/00Nanotechnology
    • Y10S977/84Manufacture, treatment, or detection of nanostructure
    • Y10S977/842Manufacture, treatment, or detection of nanostructure for carbon nanotubes or fullerenes

Definitions

  • the invention belongs to the technical field of nano materials, and in particular relates to a method for preparing graphene. Background technique
  • graphene Since graphene was discovered in 2004, it has immediately attracted great interest from the scientific community as a new type of carbon material. Graphene has a unique two-dimensional nanostructure, which has high electron transport rate, high electrical conductivity and high thermal conductivity. It is the most known mechanical strength, and has the advantages of chemical stability and good light permeability. Graphene has extremely attractive application prospects in many fields such as semiconductor industry, energy storage materials, functional composite materials, sensors and biomedicine. Therefore, the research on the basis and application of graphene has become an international research hotspot.
  • the mechanical exfoliation method and the epitaxial growth method have low production efficiency and are difficult to meet the needs of large scale.
  • chemical vapor deposition can obtain a large-sized continuous graphene film, it is suitable for micro-nanoelectronic devices or transparent conductive films, but it cannot meet the large-scale requirements in the field of energy storage materials and functional composite materials.
  • the solution phase redox method has a great improvement in the preparation scale, but the strong redox conditions in the solution phase redox method disclosed in the prior art make graphene production.
  • the solution phase redox method in the prior art is cumbersome, and the treatment of the reaction liquid is also quite difficult.
  • the prior art methods are not suitable for large-scale preparation of high quality graphene. Summary of the invention
  • the problem to be solved by the present invention is to provide a method for preparing graphene.
  • the method provided by the invention has a simple preparation process and mild reaction conditions, and the oxidation conditions used are weaker than the conventional solution phase oxidation reduction.
  • the method can produce graphene without a reduction step at a low oxidation degree, and the obtained graphene has few structural defects and excellent electrical conductivity.
  • the present invention provides a method for preparing graphene, comprising: reacting graphite in an acid solution in which an oxidant is present to obtain graphene.
  • the ratio of carbon to oxygen in the product after the reaction is greater than 5.
  • the oxidizing agent comprises nitric acid, sulfuric acid, perchloric acid, hypochlorous acid, nitrous acid, chlorosulfonic acid, dichromate, perchlorate, chlorate, hypochlorite, persulfate, hydrogen peroxide. a combination of one or more of the peroxides.
  • the acid in the acid solution is a combination of one or more of nitric acid, acid, hydrochloric acid, perchloric acid, hypochlorous acid, nitrous acid, chlorosulfonic acid, acetic acid, and oxalic acid.
  • the solvent in the acid solution comprises a combination of one or more of ethanol, carbon tetrachloride, benzene, water, methanol, acetone, formaldehyde, acetaldehyde, acetic acid.
  • the graphite comprises a combination of one or more of natural graphite, artificial graphite or expandable graphite.
  • the graphite: oxidant: acid: solvent is in a mass ratio of 1:0.1-50:0.1-50:0.1-100.
  • the temperature of the reaction is from 0 ° C to 90 ° C.
  • the reaction time is from 1 minute to 10 hours.
  • the step of washing the mixed solution after the reaction to neutral is also included.
  • the step of subjecting the graphene obtained after the reaction to a stripping treatment is further included. .
  • the peeling treatment comprises one or more of high temperature peeling, mechanical grinding or ultrasonic treatment.
  • the present invention provides a method of preparing graphene, comprising an acidic solution in which graphite is present in an oxidizing agent. The reaction is carried out to obtain graphene.
  • the invention has the advantages that the graphene prepared by the method provided by the invention has good quality and greatly improves the yield and the yield compared to the mechanical stripping, epitaxial growth and chemical vapor deposition methods.
  • the graphene of the invention has obvious improvement in mass, structural defects are greatly reduced, and electrical conductivity is remarkably improved; and the preparation process is simple, the condition is mild, the cost is low, and the scale production is very easy.
  • the graphene prepared by the invention has a very broad prospect in the fields of lithium ion batteries, supercapacitors, functional composite materials, transparent conductive films, microelectronic devices and the like.
  • Example 1 is a Raman spectrum diagram of graphene prepared in Example 1 of the present invention.
  • Fig. 2 is a Raman spectrum diagram of graphene prepared in Comparative Example 1 of the present invention. detailed description
  • the invention provides a preparation method of graphene, comprising:
  • Graphite is reacted in an acid solution containing an oxidizing agent to obtain graphene.
  • the carbon-oxygen atom ratio in the product after the reaction is more than 5, more preferably more than 10, still more preferably more than 14, more preferably more than 16, more preferably more than 20.
  • the acid in the acid solution is one or a combination of one of nitric acid, acid, perchloric acid, hypochlorous acid, nitrous acid, chlorosulfonic acid, acetic acid, and oxalic acid, but is not limited thereto.
  • the oxidizing agent is nitric acid, sulfuric acid, perchloric acid, hypochlorous acid, nitrous acid, chlorosulfonic acid, dichromate, perchlorate, chlorate, hypochlorite, persalt, hydrogen peroxide, peroxidation A combination of one or more of the substances, but is not limited thereto.
  • the solvent in the acid solution includes a combination of one or more of ethanol, carbon tetrachloride, benzene, water, methanol, acetone, formaldehyde, acetaldehyde, acetic acid, but is not limited thereto.
  • Specific examples of the dichromate are, for example, sodium dichromate, potassium dichromate, ammonium dichromate, but are not limited thereto.
  • Specific examples of the perchlorate are, for example, potassium perchlorate, sodium perchlorate, perchloric acid, and perchloric acid, but are not limited thereto.
  • Specific examples of the chlorate include, but are not limited to, potassium chlorate, sodium chlorate, and ammonium chlorate.
  • hypochlorite secondary chlorine Potassium acid, sodium hypochlorite, ammonium hypochlorite, but is not limited thereto.
  • persalt salt are, for example, potassium percarbonate, sodium persulfate, and ammonium persulfate, but are not limited thereto.
  • peroxide are, for example, sodium peroxide, potassium peroxide, peracetic acid, but are not limited thereto.
  • the graphite: oxidizing agent: acid: the solvent is in a mass ratio of 1:0.1-50:0.1-50:0.1-100, more preferably 1:0.2-40:1-40:0.2-50, more preferably It is 1:0.2-20:0.5-20:0.2-20;
  • the reaction temperature is preferably 0 ° C ⁇ 90 ° C, more preferably 10 ° C ⁇ 80 ° C, more preferably 20 ° C ⁇ 70 ° C
  • the reaction time is preferably from 1 minute to 10 hours, more preferably from 10 minutes to 9 hours, still more preferably from 30 minutes to 5 hours.
  • the method further comprises the step of performing a stripping treatment on the reacted product, wherein the stripping treatment is preferably one of high temperature peeling, mechanical grinding or ultrasonic treatment, and the above several stripping treatments may be combined, for the order,
  • the stripping treatment is preferably one of high temperature peeling, mechanical grinding or ultrasonic treatment, and the above several stripping treatments may be combined, for the order,
  • the invention is not particularly limited.
  • the use of high temperature stripping is preferably carried out as follows:
  • the product is heated to 500 ° C to 1000 ° C for heat retention, preferably to 650 ° C to 950 ° C, more preferably to 700 ° C to 800 ° C, more preferably to 750 ° C to 800 ° C.
  • the holding time is preferably at least 10 seconds, more preferably 10 seconds to 5 minutes, still more preferably 50 seconds to 3 minutes.
  • one or more of high energy ball milling, small ball sanding, oscillating grinding, and impact grinding may be used when peeling by mechanical grinding, and the grinding time is preferably at least 10 minutes, more preferably at least 15 minutes, more It is preferably at least 20 minutes, more preferably 30 minutes to 20 hours, still more preferably 2 hours to 15 hours, still more preferably 10 hours to 14 hours.
  • the sonication time is preferably from 1 minute to 10 hours, more preferably from 10 minutes to 8 hours, still more preferably from 10 minutes to 8 hours, still more preferably from 20 minutes to 6 hours, still more preferably 40 minutes to 4 hours.
  • the solvent used may be N-methylpyrrolidone, hydrazine, hydrazine-dimethylformamide, hydrazine, hydrazine-dimethylacetamide, hydrazine-methylformamide, dimethyl sulfoxide. , benzene, toluene, xylene, carbon tetrachloride, dichloromethane, chloroform, acetonitrile, acrylonitrile, dichloromethane, chlorosulfonic acid, ethanol, ethylene glycol, glycerol, isopropanol, acetone or water One or several combinations.
  • the invention Compared with the prior art, the invention has the advantages that: compared with the mechanical stripping, epitaxial growth and chemical vapor deposition methods, the graphene prepared by the method provided by the invention has good quality and greatly increases High yield and yield; Compared with the solution phase redox method, the graphene of the invention has obvious improvement in mass, structural defects are greatly reduced, conductivity is remarkably improved; and the preparation process is simple, the condition is mild, and the cost is low. Very easy to scale production.
  • the graphene prepared by the invention has a very broad prospect in the fields of lithium ion batteries, supercapacitors, functional composite materials, transparent conductive films and the like.
  • potassium dichromate is mixed with 69 wt% aqueous solution of nitric acid, followed by graphite, graphite: nitric acid: potassium dichromate: water in a weight ratio of 1:20:10:9, then reacted at 40 °C After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is kept at 900 ° C for 1 minute and then cooled to room temperature.
  • the product in the second step is ground in a high-energy ball mill or a sand mill for 5 hours; The product of the third step was dispersed in ethanol and sonicated for 1 hour to obtain graphene in a yield of 96%, and the carbon-oxygen atomic ratio of the product was 21.2.
  • potassium dichromate is mixed with a 69 wt% aqueous solution of nitric acid and a certain amount of ethanol, followed by graphite, graphite: concentrated nitric acid: potassium dichromate: water: ethanol in a weight ratio of 1:20:10: 9:10, then reacted at 40 ° C for 1 hour, washed with water until neutral and dried;
  • the product obtained in the first step is kept at 900 ° C for 1 minute and then cooled to room temperature.
  • the product in the second step is ground in a high-energy ball mill or a sand mill for 5 hours; The product in the third step was dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • potassium dichromate is mixed with a 69 wt% aqueous solution of nitric acid and a certain amount of methanol, followed by graphite, graphite: concentrated nitric acid: potassium dichromate: water: methanol in a weight ratio of 1:20:10: 9:10, then reacted at 40 ° C for 1 hour, washed with water until neutral and dried;
  • the product obtained in the first step is kept at 700 ° C for 1 minute and then cooled to room temperature.
  • the product in the second step is ground in a high-energy ball mill or a sand mill for 5 hours; The product in the third step was dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • potassium dichromate is mixed with a 69 wt% aqueous solution of nitric acid and a certain amount of acetic acid, followed by graphite, graphite: concentrated nitric acid: potassium dichromate: water: acetic acid in a weight ratio of 1:20:10: 9:20, then reacted at 40 ° C for 1 hour, washed with water until neutral and dried;
  • the product obtained in the first step is kept at 700 ° C for 1 minute and then cooled to room temperature.
  • the product in the second step is ground in a high-energy ball mill or a sand mill for 5 hours; The product in the third step was dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • sodium dichromate is mixed with 98 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: sodium dichromate in a weight ratio of 1:40:20, then reacted at 80 °C. After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is kept at 1000 ° C for 1 minute and then cooled to room temperature.
  • the product in the second step is ground in a high-energy ball mill or a sand mill for 10 hours; The product in the third step was dispersed in ethanol and sonicated for 5 hours to obtain graphene.
  • potassium perchlorate is mixed with 96 wt% of concentrated acid, followed by graphite, graphite: concentrated gram acid: potassium perchlorate in a weight ratio of 1:10:10, and then reacted at 50 ° C for 1 hour, Wash with water until neutral and dry;
  • the product obtained in the first step is kept at 600 ° C for 30 seconds and then cooled to room temperature.
  • the product in the second step is ground in a high energy ball mill or a sand mill for 1 hour; The product in the third step was dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • ammonium perchlorate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: ammonium perchlorate in a weight ratio of 1:5:0.5, then reacted at 20 °C 2 After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is kept at 800 ° C for 30 seconds and then cooled to room temperature.
  • the product in the second step is ground in a high-energy ball mill or a sand mill for 1 hour; The product in the third step was dispersed in N-methylpyrrolidone and sonicated for 1 hour to obtain graphene.
  • potassium chlorate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: potassium chlorate is 1:1:0.5 by weight, then reacted at 40 ° C for 0.5 hours, then washed with water until Neutral and dry;
  • the product obtained in the first step is kept at 800 ° C for 30 seconds, and then cooled to room temperature; in the third step, the product in the second step is ground in a high-energy ball mill or a sand mill for 1 hour;
  • the product in the third step was dispersed in N-methylpyrrolidone and sonicated for 1 hour to obtain graphene.
  • potassium chlorate is mixed with 96 ⁇ 1% concentrated acid and 69% by weight aqueous solution of nitric acid, followed by graphite, graphite: concentrated: concentrated nitric acid: potassium chlorate: water in a weight ratio of 1:1:0.5:1: 0.22, then reacted at 60 ° C for 1 hour, washed with water until neutral and dried;
  • the product obtained in the first step is kept at 800 ° C for 1 minute, and then cooled to room temperature; in the third step, the product in the second step is ground in a high-energy ball mill or a sand mill for 1 hour;
  • the product in the third step was dispersed in hydrazine, hydrazine-dimethylformamide, and sonicated for 1 hour to obtain graphene.
  • sodium chlorate is mixed with a 69 wt% aqueous solution of nitric acid, followed by graphite, graphite: nitric acid: sodium chlorate: water in a weight ratio of 1:2:2:0.9, and then reacted at 60 ° C for 1 hour. Wash with water until neutral and dry;
  • the product obtained in the first step is incubated at 700 ° C for 1 minute, and then cooled to room temperature; in the third step, the product in the second step is ground in a high energy ball mill or a sand mill for 5 hours;
  • the product of the third step was dispersed in hydrazine, hydrazine-dimethylacetamide, and sonicated for 1 hour to obtain graphene.
  • potassium chlorate is mixed with 69 wt% aqueous solution of nitric acid, followed by graphite, graphite: concentrated nitric acid: potassium chlorate: water in a weight ratio of 1:10:20:5.4, then reacted at 70 ° C for 1 hour, washed with water Neutral and dry;
  • the product obtained in the first step is kept at 700 ° C for 1 minute, and then cooled to room temperature;
  • the product in the second step was dispersed in N-methylpyrrolidone and sonicated for 1 hour to obtain graphene.
  • potassium chlorate is mixed with a 69 wt% aqueous solution of nitric acid and a certain amount, followed by graphite, graphite: concentrated nitric acid: potassium chlorate: water in a weight ratio of 1:10:20:4.5, and then reacted at 70 ° C After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is incubated at 700 ° C for 1 minute and then cooled to room temperature.
  • the product in the second step is dispersed in N-methylpyrrolidone and sonicated for 1 hour to obtain graphite. Alkene.
  • potassium dichromate is mixed with 69 wt% aqueous solution of nitric acid, followed by graphite, graphite: concentrated nitric acid: potassium dichromate: water in a weight ratio of 1:20:20:9, then reacted at 70 ° C After 1 hour, wash with water until neutral and dry;
  • the product obtained in the first step is incubated at 700 ° C for 1 minute and then cooled to room temperature.
  • the product in the second step is dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • potassium dichromate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: potassium dichromate in a weight ratio of 1:10:20, then reacted at 80 °C. After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is ground in a high energy ball mill for 2 hours;
  • the product in the second step was dispersed in N-methylpyrrolidone and sonicated for 1 hour to obtain graphene.
  • potassium dichromate is mixed with 96 ⁇ 1% concentrated sulfuric acid and acetic acid, followed by graphite, graphite: concentrated sulfuric acid: potassium dichromate: acetic acid in a weight ratio of 1:10:20:5, then After reacting at 80 ° C for 1 hour, it was washed with water until neutral and dried;
  • the product obtained in the first step is ground in a high energy ball mill for 2 hours;
  • potassium dichromate is mixed with 98 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: potassium dichromate according to weight ratio 1:20:10, then reacted at 70 °C After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is allowed to stand at 1000 ° C for 2 minutes and then cooled to room temperature.
  • the product of the second step is ground in a high-energy ball mill for 1 hour to obtain graphene.
  • potassium dichromate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: potassium dichromate in a weight ratio of 1:20:10, then reacted at 70 °C. After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is ground in a high-energy ball mill for 1 hour to obtain graphene.
  • potassium dichromate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: potassium dichromate in a weight ratio of 1:20:10, then reacted at 70 °C. After an hour, wash with water until neutral and dry;
  • the product obtained in the first step is dispersed in N-methylpyrrolidone, and the graphene is obtained by ultrasonication for 1 minute.
  • potassium persulfate is mixed with 96% by weight of concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: potassium persulfate in a weight ratio of 1:30:20, and then reacted at 40 ° C for 1 hour, with water Wash to neutral and dry;
  • the product obtained in the first step was allowed to stand at 800 ° C for 30 seconds and cooled to room temperature.
  • the product in the second step was dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • sodium persulfate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: sodium persulfate in a weight ratio of 1:20:10, and then reacted at 70 °C for 1 hour. Wash with water until neutral and dry;
  • the product obtained in the first step is dispersed in ethanol and sonicated for 1 hour to obtain graphite. Alkene.
  • ammonium persulfate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: ammonium persulfate in a weight ratio of 1:30:15, and then reacted at 40 ° C for 1 hour. Wash with water until neutral and dry;
  • the product obtained in the first step was dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • potassium persulfate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: potassium persulfate in a weight ratio of 1:30:15, and then reacted at 40 ° C for 1 hour. Wash with water until neutral and dry;
  • the product obtained in the first step was dispersed in N-methylpyrrolidone and sonicated for 1 hour to obtain graphene.
  • sodium persulfate is mixed with 96 ⁇ 1% concentrated sulfuric acid, followed by graphite, graphite: concentrated sulfuric acid: sodium persulfate in a weight ratio of 1:5:5, and then reacted at 40 ° C for 1 hour. Wash with water until neutral and dry;
  • the product obtained in the first step was dispersed in a mixed solvent of water and ethanol, and ultrasonicated for 1 hour to obtain graphene.
  • sodium persulfate is mixed with 69 wt% aqueous solution of nitric acid and acetic acid, followed by graphite, graphite: nitric acid: sodium persulfate: water: acetic acid in a weight ratio of 1:20:20:9:10, then After reacting at 40 ° C for 1 hour, wash with water until neutral and dry;
  • the product obtained in the first step was dispersed in ethanol and sonicated for 1 hour to obtain graphene.
  • a 30 wt% aqueous hydrogen peroxide solution and 96 wt% of concentrated acid are mixed, and then graphite is added.
  • the product obtained in the first step was allowed to stand at 800 ° C for 1 minute and cooled to room temperature.
  • the product in the second step was dispersed in N-methylpyrrolidone, and after 1 hour of sonication, graphene was obtained.
  • a 30 wt% aqueous hydrogen peroxide solution and a 65 wt% aqueous solution of nitric acid are mixed, followed by graphite, graphite: nitric acid: hydrogen peroxide: water in a weight ratio of 1:15:3:15, then at 75 °C After reacting for 0.2 hours, after standing for 5 hours, it was washed with water until neutral and dried;
  • the product obtained in the first step was allowed to stand at 850 ° C for 1 minute and cooled to room temperature.
  • the product in the second step was dispersed in dimethyl sulfoxide, and the mordenene was obtained after ultrasonic treatment for 1 hour.
  • nitric acid sodium peroxide: water in a weight ratio of 1:20:10:9, and then stirred at 75 ° C for 0.2 hours. Wash with water until neutral and dry;
  • the product obtained in the first step was allowed to stand at 850 ° C for 1 minute and cooled to room temperature.
  • nitric acid potassium peroxide: water in a weight ratio of 1:10:20:4.5, and then stirred at 75 ° C for 0.2 hours. Wash with water until neutral and dry;
  • the product obtained in the first step was allowed to stand at 850 ° C for 1 minute and cooled to room temperature.
  • the product of the second step is ground in a high-energy ball mill for 1 hour to obtain a graphene product.
  • peracetic acid and 65 wt% aqueous solution of nitric acid are mixed, and then graphite is added, graphite: nitric acid: peracetic acid: water in a weight ratio of 1:20:10:9, and then stirred at 75 ° C for 1.5 hours. Wash with water until neutral and dry;
  • the product obtained in the first step was allowed to stand at 850 ° C for 1 minute and cooled to room temperature.
  • the product in the second step is dispersed in isopropanol and ultrasonically treated for 1 hour.
  • Graphene product is dispersed in isopropanol and ultrasonically treated for 1 hour.
  • the product obtained in the first step was allowed to stand at 850 ° C for 1 minute and cooled to room temperature.
  • the product in the second step is ground in a high energy ball mill for 3 hours;
  • the product in the third step is dispersed in ethanol and sonicated for 2 hours to obtain a graphene product.
  • the potassium salt is mixed with 70% of a perchloric acid aqueous solution, and then graphite is added, and graphite: perchloric acid: potassium persulfate: water is 1:25:15:10.7 by weight. After stirring at 75 ° C for 1.5 hours, it was washed with water until neutral and dried;
  • the product obtained in the first step was allowed to stand at 850 ° C for 1 minute and cooled to room temperature.
  • the product in the second step is ground in a high energy ball mill for 2 hours;
  • the product in the third step is dispersed in N-methylpyrrolidone and sonicated for 2 hours to obtain a graphene product.
  • the first step is to mix potassium chlorate with chlorosulfonic acid, then add graphite, graphite: potassium chlorate: chlorosulfonic acid in a weight ratio of 1:30:18, then stir at 80 °C for 2 hours, then wash with water to neutral and dry
  • the product obtained in the first step was allowed to stand at 1000 ° C for 1 minute and cooled to room temperature.
  • the product in the second step is dispersed in N-methylformamide, and after sonication for 2 hours, graphene is obtained.
  • potassium dichromate is mixed with 96 ⁇ 1% concentrated sulfuric acid, then graphite is added, graphite: concentrated sulfuric acid: potassium dichromate is 1:33:20 by weight, then stirred at 80 °C 2 After an hour, wash with water until neutral and dry;
  • the product obtained in the first step was allowed to stand at 1000 ° C for 1 minute and cooled to room temperature.
  • the product in the second step was ground in a high energy ball mill for 1 hour.
  • the product in the third step is dispersed in N-methylpyrrolidone and sonicated for 2 hours to obtain graphene.
  • the obtained graphite oxide was ultrasonicated in an aqueous solution for 30 minutes to obtain a graphene oxide sol.
  • a sol hydrazine hydrate was added, and the mass ratio of hydrazine hydrate to graphene oxide was 1:1. After stirring uniformly, it was placed in an oven at 80 ° C for 12 hours; the obtained product was centrifuged, washed and dried, and then obtained.
  • Graphene was
  • the second step the second step, the obtained graphite oxide was ultrasonicated in an aqueous solution for 1 hour to obtain a oxidized graphene sol.
  • a sol hydrazine hydrate was added, and the mass ratio of hydrazine hydrate to graphene oxide was 1:1. After stirring uniformly, it was placed in an oven at 80 ° C for 12 hours; the obtained product was centrifuged, washed and dried, and then obtained.
  • Graphene Graphene.
  • the graphene prepared in Example 1 was subjected to structural characterization.
  • the thickness of the graphene sheet was 2-3 nm, and the size of the graphene sheet was between 1 and 50 ⁇ m.
  • Example 1 The graphene prepared in Example 1 and Comparative Example 1 was subjected to Raman spectroscopy, and the results are shown in Fig. 1 and Fig. 2, respectively. As can be seen from the results of FIGS. 1 and 2, the graphene structure defects (the D peak marked in the figure) prepared in Example 1 were significantly less than the graphene obtained by the redox of the solution phase.
  • the graphene prepared in Example 1 had a conductivity of 1000 S/cm, and the graphene prepared in Comparative Example 1 had an electric conductivity of 5 S/cm, that is, the conductivity of the graphene prepared in this example was much higher than that of oxidation.
  • Graphene prepared by a reduction method was much higher than that of oxidation.

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Description

一种制备石墨烯的方法 技术领域
本发明属于纳米材料技术领域, 具体涉及一种制备石墨烯的方法。 背景技术
自从石墨烯 2004年被发现以来, 作为一种新型碳材料立即引起了科学界 的极大兴趣。 石墨烯具有独特的二维纳米结构, 其电子传输速率高、 导电性出 色、 热导率高, 是已知的机械强度最高的物质, 而且还具有化学性质稳定和透 光性好的优点。 石墨烯在半导体工业、 储能材料、 功能复合材料、 传感器以及 生物医药等众多领域都具有极其诱人的应用前景。 因此, 围绕石墨烯的基础及 应用研究成为了国际上的研究热点。
石墨烯的制备方法是该材料能否实现实际应用的关键问题。随着研究的不 断深入,包括储能材料和功能复合材料在内的众多领域对于石墨烯的质量和制 备规模都提出了越来越高的要求。现有技术中, 已经报道的石墨烯的制备方法 有机械剥离法( K. S. Novoselov, A. K. Geim, S. V. Morozov, D. Jiang, Y. Zhang, S. V. Dubonos, I. V. Grigorieva, A. A. Firsov, Science 2004, 306, 666 )、 外延生长法 ( C. Berger, Z. M. Song, X. B. Li, X. S. Wu, N. Brown, C. Naud, D. Mayou, T. B. Li, J. Hass, A. N. Marchenkov, E. H. Conrad, P. N. First, W. A. de Heer, Science 2006, 312, 1191 )、 化学气相沉积法 ( K. S. Kim, Y. Zhao, H. Jang, S. Y. Lee, J. M. Kim, K. S. Kim, J.-H. Ahn, P. Kim, J.-Y. Choi, B. H. Hong, Nature 2009, 457, 706 ) 和溶液相氧化还原制备法( S. J. Park, R. S. Ruoff, Nature Nanotechnology 2009, 4, 217 )几种。
上述方法中,机械剥离法和外延生长法制备效率很低,难以满足大规模的 需要。化学气相沉积法虽然可以获得大尺寸连续的石墨烯薄膜,但适用于微纳 电子器件或透明导电薄膜,却不能满足储能材料及功能复合材料领域的大规模 需求。
与上述三种方法相比, 溶液相氧化还原法在制备规模上有很大提升,但现 有技术中公开的溶液相氧化还原方法中的强烈的氧化还原条件使得石墨烯产 物存在较多的缺陷, 严重影响了石墨烯的质量和性能如导电性; 此外, 现有技 术中的溶液相氧化还原法操作繁瑣,而且对于反应廈液的处理也存在相当的困 难。 综上, 现有技术中的方法都不适于大规模制备高质量的石墨烯。 发明内容
本发明要解决的问题在于提供一种制备石墨烯的方法, 与现有技术相比, 本发明提供的方法制备工艺筒单、反应条件温和, 所使用的氧化条件弱于传统 的溶液相氧化还原方法, 在低氧化程度下, 无需经过还原步骤即可制备出石墨 烯, 而且制得的石墨烯结构缺陷少, 导电性能优良。
为了解决以上技术问题, 本发明提供一种制备石墨烯的方法, 包括: 使石墨在氧化剂存在的酸溶液中进行反应得到石墨烯。
优选的, 所述的反应后的产物中的碳氧原子比大于 5.
优选的, 所述氧化剂包括硝酸、硫酸、 高氯酸、 次氯酸、 亚硝酸、 氯磺酸、 重铬酸盐、 高氯酸盐、 氯酸盐、 次氯酸盐、 过硫酸盐、 双氧水、 过氧化物中的 一种或多种的组合。
优选的, 所述的酸溶液中的酸为硝酸、 酸、 盐酸、 高氯酸、 次氯酸、 亚 硝酸、 氯磺酸、 醋酸、 草酸中的一种或多种的组合。
优选的, 所述的酸溶液中的溶剂包括乙醇、 四氯化碳、 苯、 水、 甲醇、 丙 酮、 甲醛、 乙醛、 乙酸中的一种或多种的组合。
优选的, 所述石墨包括天然石墨、人造石墨或可膨胀石墨中的一种或多种 的组合。
优选的,所述石墨:氧化剂:酸:溶剂按照质量比为 1 :0.1-50:0.1-50:0.1-100。 优选的, 所述反应的温度为 0°C ~90°C。
优选的, 所述反应的时间为 1分钟 ~10小时。 优选的, 还包括洗涤反应后 的混合液至中性的步骤。
优选的, 还包括对反应后得到的石墨烯进行剥离处理的步骤。。
优选的, 所述剥离处理包括高温剥离、机械研磨或超声处理中的一种或多 种。
本发明提供一种制备石墨烯的方法,包括使石墨在氧化剂存在的酸性溶液 中进行反应得到石墨烯。 与现有技术相比, 本发明的优点在于: 相比于机械剥 离、外延生长和化学气相沉积方法, 本发明提供的方法制备的石墨烯具有很好 的质量, 并且大幅提高了产量与产率; 相比于溶液相氧化还原方法, 本发明的 石墨烯质量具有明显的提升, 结构缺陷大大减少, 导电性显著提高; 并且, 制 备工艺筒单、 条件温和、 成本低廉、 十分易于规模化生产。 本发明制备的石墨 烯在锂离子电池、 超级电容器、 功能复合材料、 透明导电薄膜、 微电子器件等 领域具有十分广阔的前景。 附图说明
图 1为本发明实施例 1制备的石墨烯的拉曼光谱图;
图 2为本发明比较例 1制备的石墨烯的拉曼光谱图。 具体实施方式
为了进一步了解本发明, 下面结合实施例对本发明优选实施方案进行描 述, 但是应当理解, 这些描述只是为进一步说明本发明的特征和优点, 而不是 对本发明权利要求的限制。
本发明提供一种石墨烯的制备方法, 包括:
将石墨在含有氧化剂的酸溶液中反应得到石墨烯。
按照本发明, 所述的反应后的产物中的碳氧原子比大于 5 , 更优选为大于 10, 更优选为大于 14, 更优选为大于 16, 更优选为大于 20。
按照本发明, 所述酸溶液中的酸为硝酸、 酸、 高氯酸、 次氯酸、 亚硝酸、 氯磺酸、 醋酸、 草酸中的一种或多种组合, 但不限于此。 所述氧化剂为硝酸、 硫酸、 高氯酸、 次氯酸、 亚硝酸、 氯磺酸、 重铬酸盐、 高氯酸盐、 氯酸盐、 次 氯酸盐、 过 酸盐、 双氧水、 过氧化物中的一种或多种的组合, 但不限于此。 所述的酸溶液中的溶剂包括乙醇、 四氯化碳、 苯、 水、 甲醇、 丙酮、 甲醛、 乙 醛、 乙酸中的一种或多种的组合, 但不限于此。 所述重铬酸盐的具体例子如重 铬酸钠、 重铬酸钾、 重铬酸铵, 但不限于此。 所述高氯酸盐的具体例子如高氯 酸钾、 高氯酸钠、 高氯酸按、 高氯酸 4弓, 但不限于此。 所述氯酸盐中的具体例 子如氯酸钾、 氯酸钠、 氯酸铵, 但不限于此。 所述次氯酸盐的具体例子如次氯 酸钾、 次氯酸钠、 次氯酸铵, 但不限于此。 所述过 酸盐的具体例子如过 酸 钾、过硫酸钠、过硫酸铵,但不限于此。所述过氧化物的具体例子如过氧化钠、 过氧化钾、 过氧乙酸, 但不限于此。
按照本发明, 所述石墨: 氧化剂: 酸: 溶剂按照质量比为 1:0.1-50:0.1-50:0.1-100 , 更优选为 1:0.2~40:1-40:0.2-50 , 更优选为 1:0.2-20:0.5-20:0.2-20;所述反应温度优选为 0°C ~90°C ,更优选为 10°C ~80°C , 更优选为 20°C ~70°C ; 所述反应的时间优选为 1分钟 ~10小时, 更优选为 10 分钟 ~9小时, 更优选为 30分钟 ~5小时。
按照本发明, 在反应后, 优选将反应后的混合液洗涤至中性的步骤。 优选 的,还包括对反应后的产物进行剥离处理的步骤, 所述剥离处理优选为高温剥 离、 机械研磨或超声处理中的一种, 也可以将上述几种剥离处理结合处理, 对 于顺序, 本发明并无特别限制。
按照本发明, 使用高温剥离优选按照如下步骤:
将产物加热至 500 °C ~ 1000 °C进行保温,优选加热至 650°C ~950°C ,更优选 加热至 700°C ~800°C , 更优选加热至 750°C ~800°C。 保温时间优选为至少 10 秒中, 更优选为 10秒~5分钟, 更优选为 50秒~3分钟。
按照本发明, 使用机械研磨剥离时, 可以使用高能球磨、 小球介砂磨、 振 荡研磨、 冲击研磨中的一种或多种, 研磨时间优选为至少 10分钟, 更优选为 至少 15分钟, 更优选为至少 20分钟, 更优选为 30分钟 ~20小时, 更优选为 2 小时 ~15小时, 更优选为 10小时 ~14小时。
按照本发明, 使用超声剥离时, 超声处理时间优选为 1分钟 ~10小时, 更 优选为 10分钟 ~8小时, 更优选为 10分钟 ~8小时, 更优选为 20分钟 ~6小时, 更优选为 40分钟 ~4小时。
对所述产物进行超声波处理时, 所用溶剂可以为 N-甲基吡咯烷酮、 Ν,Ν- 二甲基甲酰胺、 Ν,Ν-二甲基乙酰胺、 Ν-甲基甲酰胺、 二甲亚砜、 苯、 甲苯、 二 甲苯、 四氯化碳、 二氯甲烷、 氯仿、 乙腈、 丙烯腈、 二氯甲烷、 氯磺酸、 乙醇、 乙二醇、 丙三醇、 异丙醇、 丙酮或水中的一种或几种组合。
与现有技术相比, 本发明的优点在于: 相比于机械剥离、 外延生长和化学 气相沉积方法, 本发明提供的方法制备的石墨烯具有很好的质量, 并且大幅提 高了产量与产率; 相比于溶液相氧化还原方法, 本发明的石墨烯质量具有明显 的提升, 结构缺陷大大减少, 导电性显著提高; 并且, 制备工艺筒单、 条件温 和、 成本低廉、 十分易于规模化生产。 本发明制备的石墨烯在锂离子电池、 超 级电容器、 功能复合材料、 透明导电薄膜等领域具有十分广阔的前景。
以下以具体实施例说明本发明的效果,但本发明的保护范围不受以下实施 例的限制。 实施例 1
第一步, 将重铬酸钾与 69wt%的硝酸水溶液混合, 随后加入石墨, 石墨: 硝酸: 重铬酸钾: 水按照重量比为 1 :20:10:9, 然后在 40 °C反应 1小时后, 用 水洗涤至中性并干燥;
第二步, 将第一步得到的产物于 900 °C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 5小时; 第四步, 将第三步中产物分散于乙醇中, 超声处理 1小时, 得到石墨烯, 产率为 96% , 产物的碳氧原子比为 21.2。
实施例 2
第一步,将重铬酸钾与 69wt%^々硝酸水溶液以及一定量的乙醇混合, 随后 加入石墨, 石墨: 浓硝酸: 重铬酸钾: 水: 乙醇按照重量比为 1 :20:10:9:10, 然后在 40°C反应 1小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物于 900 °C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 5小时; 第四步, 将第三步中产物分散于乙醇中, 超声处理 1小时, 得到石墨烯。 实施例 3
第一步,将重铬酸钾与 69wt%^々硝酸水溶液以及一定量的甲醇混合, 随后 加入石墨, 石墨: 浓硝酸: 重铬酸钾: 水: 甲醇按照重量比为 1 :20:10:9:10, 然后在 40°C反应 1小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物于 700°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 5小时; 第四步, 将第三步中产物分散于乙醇中, 超声处理 1小时, 得到石墨烯。 实施例 4
第一步,将重铬酸钾与 69wt%^々硝酸水溶液以及一定量的乙酸混合, 随后 加入石墨, 石墨: 浓硝酸: 重铬酸钾: 水: 乙酸按照重量比为 1 :20:10:9:20, 然后在 40°C反应 1小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物于 700°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 5小时; 第四步, 将第三步中产物分散于乙醇中, 超声处理 1小时, 得到石墨烯。 实施例 5
第一步, 将重铬酸钠与 98\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 重铬酸钠按照重量比为 1 :40:20, 然后在 80 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物于 1000°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 10小时; 第四步, 将第三步中产物分散于乙醇中, 超声处理 5小时, 得到石墨烯。 实施例 6
第一步, 将高氯酸钾与 96wt%的浓^ £酸混合, 随后加入石墨, 石墨: 浓石克 酸: 高氯酸钾按照重量比为 1 :10:10, 然后在 50°C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物于 600°C保温 30秒钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 1小时; 第四步, 将第三步中产物分散于乙醇中, 超声处理 1小时, 得到石墨烯。 实施例 7
第一步, 将高氯酸铵与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 高氯酸铵按照重量比为 1 :5:0.5 , 然后在 20 °C反应 2小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物于 800°C保温 30秒钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 1小时; 第四步, 将第三步中产物分散于 N-甲基吡咯烷酮中, 超声处理 1小时, 得到石墨烯。 第一步,将氯酸钾与 96\¥1%的浓硫酸混合, 随后加入石墨,石墨: 浓硫酸: 氯酸钾按照重量比为 1 :1 :0.5 , 然后在 40°C反应 0.5小时后,用水洗涤至中性并 干燥;
第二步, 将第一步得到的产物于 800°C保温 30秒钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 1小时;
第四步, 将第三步中产物分散于 N-甲基吡咯烷酮中, 超声处理 1小时, 得到石墨烯。
实施例 9
第一步, 将氯酸钾与 96\¥1%的浓 酸和 69wt%的硝酸水溶液混合, 随后 加入石墨, 石墨: 浓 吏: 浓硝酸: 氯酸钾: 水按照重量比为 1 :1 :0.5:1 :0.22, 然后在 60°C反应 1小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物于 800°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 1小时;
第四步, 将第三步中产物分散于 Ν,Ν-二甲基甲酰胺中, 超声处理 1小时, 得到石墨烯。
实施例 10
第一步, 将氯酸钠与 69wt%的硝酸水溶液混合, 随后加入石墨, 石墨: 硝 酸: 氯酸钠: 水按照重量比为 1 :2:2:0.9, 然后在 60 °C反应 1小时后, 用水洗涤 至中性并干燥;
第二步, 将第一步得到的产物于 700°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物于高能球磨机或砂磨机中研磨 5小时;
第四步, 将第三步中产物分散于 Ν,Ν-二甲基乙酰胺中, 超声处理 1小时, 得到石墨烯。
实施例 11
第一步, 将氯酸钾与 69wt%的硝酸水溶液混合, 随后加入石墨, 石墨: 浓 硝酸: 氯酸钾: 水按照重量比为 1 :10:20:5.4, 然后在 70 °C反应 1小时后, 用水 洗涤至中性并干燥;
第二步, 将第一步得到的产物于 700°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物分散于 N-甲基吡咯烷酮中, 超声处理 1小时, 得到石墨烯。
实施例 12
第一步,将氯酸钾与 69wt%^々硝酸水溶液以及一定量的混合, 随后加入石 墨, 石墨: 浓硝酸: 氯酸钾: 水按照重量比为 1 :10:20:4.5 , 然后在 70°C反应 1 小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物于 700°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物分散于 N-甲基吡咯烷酮中, 超声处理 1小时, 得到石墨烯。
实施例 13
第一步, 将重铬酸钾与 69wt%的硝酸水溶液混合, 随后加入石墨, 石墨: 浓硝酸: 重铬酸钾: 水按照重量比为 1 :20:20:9, 然后在 70°C反应 1小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物于 700°C保温 1分钟, 然后冷却至室温; 第三步, 将第二步中产物分散于乙醇中, 超声处理 1小时, 得到石墨烯。 实施例 14
第一步, 将重铬酸钾与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 重铬酸钾按照重量比为 1 :10:20, 然后在 80 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物于高能球磨机中研磨 2小时;
第三步, 将第二步中产物分散于 N-甲基吡咯烷酮中, 超声处理 1小时, 得到石墨烯。
实施例 15
第一步,将重铬酸钾与 96\¥1%的浓硫酸和乙酸混合,随后加入石墨,石墨: 浓硫酸: 重铬酸钾: 乙酸按照重量比为 1:10:20:5 , 然后在 80°C反应 1小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物于高能球磨机中研磨 2小时;
第三步, 将第二步中产物分散于 N-甲基吡咯烷酮中, 超声处理 1小时, 得到石墨烯。 实施例 16
第一步, 将重铬酸钾与 98\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 重铬酸钾按照重量比为 1 :20:10, 然后在 70 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物于 1000 °C放置 2分钟, 然后冷却至室温; 第三步,将第二步所的产物于高能球磨机中研磨 1小时,即可获得石墨烯。 实施例 17
第一步, 将重铬酸钾与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 重铬酸钾按照重量比为 1 :20:10, 然后在 70 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步,将第一步得到的产物于高能球磨机中研磨 1小时, 即可获得石墨 烯。
实施例 18
第一步, 将重铬酸钾与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 重铬酸钾按照重量比为 1 :20:10, 然后在 70 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物分散于 N-甲基吡咯烷酮中, 超声处理 1分 钟, 即可获得石墨烯。
实施例 19
第一步, 将过硫酸钾与 96wt%^々浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 过硫酸钾按照重量比为 1 :30:20, 然后在 40 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物于 800 °C下放置 30秒钟, 冷却至室温; 第三步, 将第二步中产物分散于乙醇中, 超声处理 1小时, 获得石墨烯。 实施例 20
第一步, 将过硫酸钠与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 过硫酸钠按照重量比为 1 :20:10, 然后在 70 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物分散于乙醇中, 超声处理 1小时, 获得石墨 烯。
实施例 21
第一步, 将过硫酸铵与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 过硫酸铵按照重量比为 1 :30:15 , 然后在 40 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物分散于乙醇中, 超声处理 1小时, 获得石墨 烯。
实施例 22
第一步, 将过硫酸钾与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 过硫酸钾按照重量比为 1 :30:15 , 然后在 40 °C反应 1小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步得到的产物分散于 N-甲基吡咯烷酮中, 超声处理 1小 时, 获得石墨烯。
实施例 23
第一步, 将过硫酸钠与 96\¥1%的浓硫酸混合, 随后加入石墨, 石墨: 浓硫 酸: 过硫酸钠按照重量比为 1 :5:5 , 然后在 40 °C反应 1小时后, 用水洗涤至中 性并干燥;
第二步, 将第一步得到的产物分散于水和乙醇的混合溶剂中, 超声处理 1 小时, 获得石墨烯。
实施例 24
第一步, 将过硫酸钠与 69wt%^々硝酸水溶液和乙酸混合, 随后加入石墨, 石墨: 硝酸: 过硫酸钠: 水: 乙酸按照重量比为 1 :20:20:9:10, 然后在 40°C反 应 1小时后, 用水洗涤至中性并干燥;
第二步, 将第一步得到的产物分散于乙醇中, 超声处理 1小时, 获得石墨 烯。
实施例 25
第一步, 将 30wt%的过氧化氢水溶液和 96wt%的浓^ i酸混合, 然后加入 石墨, 石墨: 浓 ^£酸: 过氧化氢: 水按照重量比为 1 :20:3:7, 然后在 75 °C反应 0.5小时后, 用水洗涤至中性并干燥; 第二步, 将第一步所得产物于 800°C放置 1分钟, 并冷却至室温。
第三步, 将第二步中产物分散于 N-甲基吡咯烷酮中, 超声处理 1小时后 获得石墨烯。
实施例 26
第一步, 将 30wt%的过氧化氢水溶液和 65wt%的硝酸水溶液混合, 然后 加入石墨, 石墨: 硝酸: 过氧化氢: 水按照重量比为 1 :15:3:15 , 然后在 75 °C 反应 0.2小时后, 静置 5小时后, 用水洗涤至中性并干燥;
第二步, 将第一步所得产物于 850°C放置 1分钟, 并冷却至室温。
第三步,将第二步中产物分散于二甲基亚砜中,超声处理 1小时后获得石 墨烯。
实施例 27
第一步, 将过氧化钠和 65wt%的硝酸水溶液混合, 然后加入石墨, 石墨: 硝酸: 过氧化钠: 水按照重量比为 1 :20: 10:9, 然后在 75 °C搅拌 0.2小时后, 用 水洗涤至中性并干燥;
第二步, 将第一步所得产物于 850°C放置 1分钟, 并冷却至室温。
第三步, 将第二步中产物分散于氯仿中, 超声处理 1小时后获得石墨烯。 实施例 28
第一步, 将过氧化钾和 65wt%的硝酸水溶液混合, 然后加入石墨, 石墨: 硝酸: 过氧化钾: 水按照重量比为 1 :10:20:4.5 , 然后在 75 °C搅拌 0.2小时后, 用水洗涤至中性并干燥;
第二步, 将第一步所得产物于 850°C放置 1分钟, 并冷却至室温。
第三步,将第二步中产物于高能球磨机中研磨 1小时, 即可获得石墨烯产 物。
实施例 29
第一步, 将过氧乙酸和 65wt%的硝酸水溶液混合, 然后加入石墨, 石墨: 硝酸: 过氧乙酸: 水按照重量比为 1 :20: 10:9, 然后在 75 °C搅拌 1.5小时后, 用 水洗涤至中性并干燥;
第二步, 将第一步所得产物于 850°C放置 1分钟, 并冷却至室温。
第三步, 将第二步中产物分散于异丙醇中, 超声波处理 1小时, 即可获得 石墨烯产物。
实施例 30
第一步,将重铬酸钾和 70\¥1%的高氯酸水溶液混合,然后加入石墨,石墨: 高氯酸: 重铬酸钾: 水按照重量比为 1 :30:20:12.9, 然后在 75 °C搅拌 1.5小时 后, 用水洗涤至中性并干燥;
第二步, 将第一步所得产物于 850°C放置 1分钟, 并冷却至室温。
第三步, 将第二步中产物于高能球磨机中研磨 3小时;
第四步, 将第三步中产物分散于乙醇中, 超声处理 2小时, 即可获得石墨 烯产物。
实施例 31
第一步,将过 ^£酸钾与 70\¥1%的高氯酸水溶液混合,然后加入石墨,石墨: 高氯酸: 过硫酸钾: 水按照重量比为 1 :25:15:10.7, 然后在 75 °C搅拌 1.5小时 后, 用水洗涤至中性并干燥;
第二步, 将第一步所得产物于 850°C放置 1分钟, 并冷却至室温。
第三步, 将第二步中产物于高能球磨机中研磨 2小时;
第四步, 将第三步中产物分散于 N-甲基吡咯烷酮中, 超声处理 2小时, 即可获得石墨烯产物。
实施例 32
第一步, 将氯酸钾与氯磺酸混合, 然后加入石墨, 石墨: 氯酸钾: 氯磺酸 按照重量比为 1 :30:18, 然后在 80 °C搅拌 2小时后, 用水洗涤至中性并干燥; 第二步, 将第一步所得产物于 1000°C放置 1分钟, 并冷却至室温。
第三步, 将第二步中产物分散于 N-甲基甲酰胺中, 超声处理 2小时后, 即可获得石墨烯。
实施例 33
第一步, 将重铬酸钾与 96\¥1%的浓硫酸混合, 然后加入石墨, 石墨: 浓硫 酸: 重铬酸钾按照重量比为 1 :33:20, 然后在 80 °C搅拌 2小时后, 用水洗涤至 中性并干燥;
第二步, 将第一步所得产物于 1000°C放置 1分钟, 并冷却至室温。
第三步, 将第二步中产物于高能球磨机中研磨 1小时。 第四步, 将第三步中产物分散于 N-甲基吡咯烷酮中, 超声处理 2小时, 即可得到石墨烯。
比较例 1 溶液相氧化还原法制备石墨烯
第一步, 称取 1.2克硝酸钾, 加入 46毫升 96wt%的浓硫酸中, 然后加入 1.0克石墨, 混合均匀后, 搅拌下緩慢加入 6.0克高锰酸钾。 然后将混合物加 热至 40°C , 继续搅拌 6小时。 再緩慢滴入 80毫升水, 将体系升温至 70°C后搅 拌 30分钟。 加入 200毫升去离子水和 6毫升 30wt%的双氧水, 搅拌 5分钟后 停止。 将反应后的产物用去离子水洗涤至若干次至体系 pH值达到 5 , 得到氧 化石墨。
第二步, 将得到的氧化石墨在水溶液中超声处理 30分钟, 得到氧化石墨 烯溶胶。 向所述溶胶中加入水合肼, 水合肼与氧化石墨烯的质量比为 1 :1 , 搅 拌均匀后, 放置于 80°C烘箱中 12小时; 将得到的产物离心、 洗涤干燥后, 即 可获得石墨烯。
比较例 2 溶液相氧化还原法制备石墨烯
第一步, 称取 1.0克石墨, 加入 20毫升 96wt%的浓硫酸中, 随后加入 3.0 克高氯酸钾, 在 0 °C的冰水浴中搅拌反应 2小时。 随后将体系升温至 40 °C, 并在此温度下继续搅拌反应 12小时。 然后加入 200毫升去离子水, 将体系升 温至 90 °C, 并继续搅拌 30分钟后冷却至室温。将反应产物用去离子水用去离 子水洗涤至若干次至体系 pH值达到 5 , 得到氧化石墨。
第二步, 第二步, 将得到的氧化石墨在水溶液中超声处理 1小时, 得到氧 化石墨烯溶胶。 向所述溶胶中加入水合肼, 水合肼与氧化石墨烯的质量比为 1:1 , 搅拌均匀后, 放置于 80°C烘箱中 12小时; 将得到的产物离心、 洗涤干燥 后, 即可获得石墨烯。
表征和性能测试
取实施例 1制备的石墨烯进行结构表征, 石墨烯片层的厚度为 2-3纳米, 石墨烯片层的尺寸分布在 1-50微米之间。
取实施例 1和比较例 1制备的石墨烯进行拉曼光谱测试, 结果分别如图 1 和图 2所示。从图 1和图 2的结果可以看出, 实施例 1制备的石墨烯结构缺陷 (图中标注的 D峰) 明显少于溶液相氧化还原获得的石墨烯。 通过 X射线光 电子能谱测得实施例 1制备的石墨烯的碳氧原子比为 21.2,而比较例 1中还原 前的氧化石墨烯的碳氧原子比为 1.2 , 还原后的石墨烯的碳氧原子比也仅为 10.1 , 即本实施例提供的制备方法对于石墨烯的氧化程度明显低于溶液相氧化 还原方法, 对于石墨烯结构的破坏程度也要低得多。 另外, 测得实施例 1制备 的石墨烯电导率为 1000 S/cm, 比较例 1制备的石墨烯的电导率为 5 S/cm, 即 本实施例制备的石墨烯的电导率远高于氧化还原方法制备的石墨烯。
对实施例 2-实施例 33 ,及比较例 2制备的石墨烯进行了结构和性能表征, 结果如表 1所示:
表 1 实施例 2-实施例 33及比较例 2制备的石墨烯性能表征结果
编号 产率 (%) 碳氧原子比 电导率 S/cm
实施例 2 93 19. 8 1000
27. 6
实施例 3 95 1200
21. 2
实施例 4 95 900
24
实施例 5 90 1000
18. 2
实施例 6 95 500
20
实施例 7 96 800
17. 2
实施例 8 95 500
19
实施例 9 88 750
18. 5
实施例 10 93 600
23. 4
实施例 11 94 900
26
实施例 12 95 1000
16. 5
实施例 13 96 500
17. 2
实施例 14 95 600
19
实施例 15 92 500
19. 8
实施例 16 96 700
22. 3
实施例 17 90 900
19. 8
实施例 18 93 750
17. 2
实施例 19 96 500 19
实施例 20 92 700
21. 2
实施例 21 95 800
21
实施例 22 92 1000
20. 3
实施例 23 93 800
22. 2
实施例 24 95 1200
17. 5
实施例 25 92 500
19. 8
实施例 26 95 700
21. 7
实施例 27 95 800
21. 2
实施例 28 88 1000
15. 9
实施例 29 89 500
17. 5
实施例 30 90 550
19
实施例 31 90 750
21. 2
实施例 32 92 900
20. 3
实施例 33 93 800
1. 8 (还原前)
比较例 2 95 10
10. 8 (还原后) 本发明提出的一种高质量石墨烯的高效制备方法已通过实施例进行了描 述,相关技术人员明显能在不脱离本发明内容、精神和范围内对本文所述的石 墨烯的制备方法进行改动或适当变更与组合, 来实现本发明技术。特别需要指 出的是, 所有相类似的替换和改动对本领域技术人员来说是显而易见的, 它们 都被视为包括在本发明的精神、 范围和内容中。

Claims

I、 一种制备石墨烯的方法, 其特征在于, 包括:
使石墨在氧化剂存在的酸溶液中进行反应得到石墨烯。
2、 根据权利要求 1所述的方法, 其特征在于, 所述反应后的产物中的碳 氧原子比大于 5 , 更优选为大于 10, 更优选为大于 14, 更优选为大于 16, 更 权
优选为大于 20。。
3、 根据权利要求 1所述的方法利, 其特征在于, 所述的酸溶液中的酸包含
1
硝酸、 石克酸、 高氯酸、 次氯酸、 亚硝酸 6、要氯磺酸、 醋酸、 草酸中的一种或多种 的组合。
4、 根据权利要求 1所述的方法, 其特征在于, 所述氧化剂包含硝酸、 硫 酸、 高氯酸、 盐酸、 次氯酸、 亚硝酸、 氯磺酸、 重铬酸盐、 高氯酸盐、 氯酸盐、 次氯酸盐、 过 酸盐、 双氧水、 过氧化物中的一种或多种的组合。
5、 根据权利要求 1所述的方法, 其特征在于, 所述的酸溶液中的溶剂包 括乙醇、 四氯化碳、 苯、 水、 甲醇、 丙酮、 甲醛、 乙醛、 乙酸中的一种或多种 的组合。
6、 根据权利要求 1所述的方法, 其特征在于, 石墨: 酸: 氧化剂: 溶剂 按照质量比优选为 1:0.1-50:0.1-50:0.1-100。
7、 根据权利要求 1所述的方法, 其特征在于, 所述反应的温度为 0°C ~90 °C。
8、 根据权利要求 1所述的方法, 其特征在于, 所述反应的时间为 1分钟 -10小时。
9、 根据权利要求 1所述的方法, 其特征在于, 还包括洗涤反应后的混合 液至中性的步骤。
10、 根据权利要求 1所述的方法, 其特征在于, 还包括对所述反应后的产 物进行剥离处理的步骤。
II、 根据权利要求 9所述的方法, 其特征在于, 所述剥离处理包括高温剥 离、 机械研磨或超声处理中的一种或多种。
PCT/CN2011/073458 2011-04-28 2011-04-28 一种制备石墨烯的方法 WO2012145911A1 (zh)

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