Specifications

size - Powders - Sintering - Solid solutions - Titanium dioxide

Uncontrolled terms: Hydrogen-reduction - Lattice distortions - Milled powders -

Milling process - Reduction temperatures - Sintering process - Solid phase sintering -

Solid-phase

Products Generally - 943.2 Mechanical Variables Measurements - 723.5 Computer

Applications - 542.3 Titanium and Alloys - 536.1 Powder Metallurgy Operations -

Title: Microstructure and properties of Cu/V0.97W0.03O2 composite material

Authors: Zou, Jun-Tao1 ; Zhang, Le1 ; Wang, Xian-Hui1 ; Huang, Xing1 ; Liang, Shu-Hua1/邹军涛;

Author affiliation: 1 School of Materials Science and Engineering, Xi'an University of

Technology, Xi'an 710048, China

Corresponding author: Wang, X.-H. (xhwang693@xaut.edu.cn)

Source title: Fenmo Yejin Cailiao Kexue yu Gongcheng/Materials Science and Engineering of

Powder Metallurgy

Abbreviated source title: Fenmo Yejin Cailiao Kexue yu Gongcheng

Volume: 18

Document type: Journal article (JA)

Publisher: Central South University, Lushan Nanlu, Changsha, 410043, China

Abstract: Cu/V0.97W0.03O2 composite materials were prepared by powder metallurgy. The

composition and surface microstructure were analyzed by SEM and EDS, the crystals structure in

room temperature was detected by XRD, the conductivity of different V0.97W0.03O2 doping

rates composite during changing temperature was tested by Eddy current electric conductance

meter. The results indicate that Cu/V0.97W0.03O2 composite materials exhibit an abrupt change

of conductivity when the temperature is near 0°C, the range of change increases with increasing

the amount of V0.97W0.03O2. Meanwhile, the crystal structure of V0.97W0.03O2 in

Cu/V0.97W0.03O2 composite materials is the same as tetragon phase VO2, which indicates that