Conductive Mg-P co-doped Cu2V2O7-graphene negative thermal expansion material and preparation method thereof

A negative thermal expansion material, graphene technology, applied in the field of negative thermal expansion materials, can solve the problems of low electrical conductivity, poor expansion performance and low electrical conductivity of negative thermal expansion materials, and achieves reduction of agglomeration and agglomeration, reduction of stress effects, high The effect of conductivity

Inactive Publication Date: 2020-05-19
管玲飞
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Problems solved by technology

[0005] Aiming at the deficiencies of the prior art, the present invention provides a conductive Mg-P co-doped Cu 2 V 2 o 7 -Graphene negative thermal expansion material and its preparation method solve the problem of high phase transition temperature and poor expansion performance of negative thermal expansion material, and solve the problem of low electrical conductivity and low electrical conductivity of negative thermal expansion material at the same time

Method used

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preparation example Construction

[0024] In order to achieve the above object, the present invention provides the following specific implementation methods and examples: a conductive Mg-P co-doped Cu 2V 2 o 7 -Graphene negative thermal expansion material and preparation method thereof, including the following formula raw materials in parts by weight: 20-30 parts of graphene oxide, 22-26.5 parts of CuO, 2.5-6 parts of MgO, 36-37 parts of V 2 o 5 , 7-13 NH 4 h 2 PO 4 , Graphene oxide is a single layer of graphene oxide with a sheet diameter of 1-5um and a thickness of 0.8-1.2nm.

[0025] Conductive Mg-P co-doped Cu 2 V 2 o 7 -The preparation method of graphene negative thermal expansion material comprises the following steps:

[0026] (1) Add an appropriate amount of absolute ethanol solvent to the planetary ball mill, add 22-26.5 parts of CuO, 2.5-6 parts of MgO and 36-37 parts of V 2 o 5 , the molar ratio of the three substances is 1.3-1.7:1:0.3-0.7, the revolution speed of the ball mill is 40-60rpm...

Embodiment 1

[0032] (1) Preparation of Cu 1.7 Mg 0.3 V 2 o 7 Loaded graphene oxide component 1: add an appropriate amount of absolute ethanol solvent to the planetary ball mill, add 26.5 parts of CuO, 2.5 parts of MgO and 36 parts of V 2 o 5 , the revolution speed of the ball mill is 40rpm, the rotation speed is 600rpm, and the ball mill is carried out for 10h until the materials pass through a 500-mesh sieve, then the materials are placed in a blower dryer, heated to 70°C, the absolute ethanol is evaporated, and the solid mixture is fully dried , add an appropriate amount of distilled water to the reaction bottle, and then 30 parts of graphene oxide and solid mixture in sequence, place the reaction bottle in an ultrasonic processor, heat it to 70°C, and perform ultrasonic treatment for 2 hours. The ultrasonic frequency is 20KHz, and the solution is passed through a high-speed The centrifuge removes the solvent, and the solid product is fully dried, and the solid product is placed in a...

Embodiment 2

[0035] (1) Preparation of Cu 1.5 Mg 0.5 V 2 o 7 Loaded graphene oxide component 2: add an appropriate amount of absolute ethanol solvent to the planetary ball mill, add 24.2 parts of CuO, 4.3 parts of MgO and 36.5 parts of V 2 o 5 , the revolution speed of the ball mill is 60rpm, the rotation speed is 600rpm, and the ball mill is carried out for 18 hours until all the materials pass through a 600-mesh sieve, then the materials are placed in a blast dryer, heated to 70°C, and the absolute ethanol is evaporated, and the solid mixture is fully dried , add an appropriate amount of distilled water to the reaction bottle, and then 26 parts of graphene oxide and solid mixture in sequence, place the reaction bottle in an ultrasonic processor, heat it to 80°C, and perform ultrasonic treatment for 2 hours, the ultrasonic frequency is 22KHz, and the solution is passed through a high-speed The centrifuge removes the solvent, and the solid product is fully dried, and the solid product ...

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Abstract

The invention relates to the technical field of negative thermal expansion materials, and discloses a conductive Mg-P co-doped Cu2V2O7-graphene negative thermal expansion material and a preparation method thereof. The conductive Mg-P co-doped Cu2V2O7-graphene negative thermal expansion material comprises the following formula raw materials: graphene oxide, CuO, MgO, V2O5 and NH4H2PO4. According tothe conductive Mg-P co-doped Cu2V2O7-graphene negative thermal expansion material and the preparation method thereof, Cu2V2O7 has a stable linear negative thermal expansion coefficient, a centrosymmetric monoclinic phase structure is formed by doping Cu2V2O7 with Mg, under temperature variation, the Mg-O bond generates a vibration effect, the internal coupling effect of the Cu2V2O7 crystal is improved, a linear chain-shaped monoclinic phase in the crystal is destroyed, oxygen atoms form a new arrangement in the crystal lattice, local collapse occurs, the Cu2V2O7 is enabled to show a negativethermal expansion phenomenon, P atoms replace part of V atoms, the grain size of Cu2V2O7 is reduced, the bond energy of P-O bonds is larger than that of V-O bonds, stress in Cu2V2O7 lattices is reduced, lattice distortion is reduced, the electron scattering probability and the high-frequency dielectric constant are reduced, and therefore the conductivity of Cu2V2O7 is enhanced.

Description

technical field [0001] The invention relates to the technical field of negative thermal expansion materials, in particular to a conductive Mg-P co-doped Cu 2 V 2 o 7 -Graphene negative thermal expansion material and its preparation method. Background technique [0002] Thermal expansion and contraction are a natural phenomenon of most materials. During application, materials will undergo volumetric deformation due to temperature changes. Devices made of different materials will generate heat due to the mismatch of expansion coefficients under temperature changes. Stress reduces the physical properties of the device. Negative thermal expansion refers to compounds whose average linear expansion coefficient or volume expansion coefficient is negative within a certain temperature range. Negative thermal expansion materials expand with cold and shrink with heat under temperature changes, and the thermal expansion coefficient has a superposition Negative thermal expansion mater...

Claims

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Application Information

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Patent Type & Authority Applications(China)
IPC IPC(8): C01B25/45C01B32/184
CPCC01B25/45C01P2004/80C01B32/184
Inventor 管玲飞
Owner 管玲飞
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