Graphene composite nano-material and preparation method and application thereof

A composite nanomaterial, graphene composite technology, applied in separation methods, chemical instruments and methods, special compound water treatment, etc., to achieve the effects of excellent performance, large surface-loaded free charge density, and high conductivity

Active Publication Date: 2017-07-04
威海千千鸟家纺有限公司
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

However, there is no report in the prior art to double chemically modify graphene with B and N doping at the same time to improve its performance.

Method used

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  • Graphene composite nano-material and preparation method and application thereof
  • Graphene composite nano-material and preparation method and application thereof

Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0023] A preparation method of a graphene composite nanomaterial, specifically comprising the steps of:

[0024] (1) Preparation of boron-nitrogen co-doped graphene: Weigh 15g of graphene oxide, add 30mL of deionized water, and ultrasonically disperse to obtain a graphene oxide dispersion, and then add 1.0 oz. g sodium borohydride and 2 g urea, and transfer the obtained mixed solution to a hydrothermal reaction kettle for 16 hours at 180° C. to obtain a precipitate, wash and dry to obtain boron-nitrogen co-doped graphene;

[0025] (2)TiO 2 / Preparation of boron-nitrogen co-doped graphene material: Take 4g of hexadecylamine and add it to 1.5mL of 0.1mol / L potassium chloride aqueous solution and 160mL of absolute ethanol, ultrasonically, and then slowly add 8mL of isopropyl titanate to react 18 hours, filtered, washed, dried to obtain TiO 2 Precursor; then get 16g of boron-nitrogen co-doped graphene in step (1) and add 80mL of ethanol, ultrasonic for about 1h to form a dispers...

Embodiment 2

[0027] A preparation method of a graphene composite nanomaterial, specifically comprising the steps of:

[0028] (1) Preparation of boron-nitrogen co-doped graphene: Weigh 10g of graphene oxide, add 20mL of deionized water, and ultrasonically disperse to obtain a graphene oxide dispersion, and then add 0.5 g sodium borohydride and 1 g urea, and transfer the resulting mixed solution to a hydrothermal reaction kettle for 18 hours at 150°C to obtain a precipitate, wash and dry to obtain boron-nitrogen co-doped graphene;

[0029] (2)TiO 2 / Preparation of boron-nitrogen co-doped graphene material: Take 3g hexadecylamine and add it to 1mL concentration of 0.15mol / L potassium chloride aqueous solution and 120mL absolute ethanol, sonicate, then slowly add 5mL isopropyl titanate to react for 15 hours, filtered, washed, and dried to obtain TiO 2 Precursor; then get 10g of boron-nitrogen co-doped graphene in step (1) and add 60mL of ethanol, ultrasonic for about 1h to form a dispersion...

Embodiment 3

[0031] A preparation method of a graphene composite nanomaterial, specifically comprising the steps of:

[0032] (1) Preparation of boron-nitrogen co-doped graphene: Weigh 20g of graphene oxide, add 40mL of deionized water, and ultrasonically disperse to obtain a graphene oxide dispersion, and then add 1.5 oz. g of sodium borohydride and 1 to 3 g of urea, and transfer the resulting mixed solution to a hydrothermal reactor at 200°C for 12 hours to obtain a precipitate, which is washed and dried to obtain boron-nitrogen co-doped graphene;

[0033] (2)TiO 2 / Preparation of boron-nitrogen co-doped graphene material: Take 3-5g of hexadecylamine and add it to 2mL of 0.05mol / L potassium chloride aqueous solution and 240mL of absolute ethanol, ultrasonically, and then slowly add 0mL of isopropyl titanate React for 20 hours, filter, wash and dry to obtain TiO 2 Precursor; then take 20g of boron-nitrogen co-doped graphene in step (1) and add 100mL of ethanol, ultrasonic for about 1h t...

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Abstract

The invention provides a graphene composite nano-material and a preparation method thereof. Through dual modification effects of B and N, on one hand, compared with the undoped graphene, the graphene composite nano-material has higher conductivity and larger surface load free charge density, and can effectively restore the structural defect of the graphene oxide simultaneously, so that doped graphene with good light performance and stability is formed; on the other hand, through coupling of titanium dioxide and doped graphene, synergetic and complementary effect is generated, photo-induced electron is transmitted to an energy band of graphene, cavity and electronic composite rate are reduced, a forbidden band of titanium dioxide is narrowed, a light response scope is expended, so that the photocatalysis performance is greatly improved, and the composite material performance is excellent.

Description

technical field [0001] The invention belongs to the technical field of application of nanomaterials, and in particular relates to a graphene composite nanomaterial and its preparation method and application. Background technique [0002] The study of nanomaterials is a frontier field in today's scientific research, and it is also a hot spot studied by many scientists all over the world. The magic and unknown aspects of nanomaterials have aroused people's widespread attention; the research and application of nanomaterials are currently hot spots and difficulties, and are also the focus of high-tech development. [0003] Photocatalytic technology is a hot spot in scientific research today, and its application range is very wide, such as sewage treatment, air purification, solar energy utilization, antibacterial, anti-fog, and self-cleaning functions. The development of photocatalytic technology mainly depends on the innovation and development of photocatalytic materials. The ...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): B01J27/24C02F1/30B01D53/86C25B1/04C25B11/06
CPCB01D53/86B01D2255/802B01J27/24B01J35/004C02F1/30C02F2305/10C25B1/04C25B11/04C25B1/55Y02E60/36Y02W10/37
Inventor 王衍根赵兴旺
Owner 威海千千鸟家纺有限公司
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