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Characterization of electrical conductivity of porous metal fiber sintered sheet using four-point probe method
Highlights ► We used four-point probe method to measure the electrical conductivity of PMFSS. ► Uniform probe spacing was adopted to measure the electrical conductivity. ► The electrical conductivity decreased with increasing porosity. ► The higher electrical conductivity was obtained under higher sintering temperature. ► Longer holding time also lead to the increase of electrical conductivity.
Abstract Novel porous metal fiber sintered sheets (PMFSSs) with different porosities were fabricated by sintering copper fibers. Using four-point probe method, comparative study was conducted to investigate the effects of probe spacing, porosity, and sintering condition on the electrical conductivity of PMFSS. Our experimental results showed that probe spacing plays an important role in determining the electrical conductivity. Uniform probe spacing was adopted in order to reduce the error caused by non-uniformity of probe spacing. The measured electrical conductivity was found to decrease with increasing porosity ranging from 70% to 90% for the PMFSS produced under the same sintering condition. Our experimental results were found to agree well with the theoretical prediction by Liu’s model for the PMFSS with different porosities. The effect of sintering condition on electrical conductivity was also investigated. It was revealed that higher sintering temperature or longer holding time yields higher electrical conductivity of PMFSS.
Characterization of electrical conductivity of porous metal fiber sintered sheet using four-point probe method
Highlights ► We used four-point probe method to measure the electrical conductivity of PMFSS. ► Uniform probe spacing was adopted to measure the electrical conductivity. ► The electrical conductivity decreased with increasing porosity. ► The higher electrical conductivity was obtained under higher sintering temperature. ► Longer holding time also lead to the increase of electrical conductivity.
Abstract Novel porous metal fiber sintered sheets (PMFSSs) with different porosities were fabricated by sintering copper fibers. Using four-point probe method, comparative study was conducted to investigate the effects of probe spacing, porosity, and sintering condition on the electrical conductivity of PMFSS. Our experimental results showed that probe spacing plays an important role in determining the electrical conductivity. Uniform probe spacing was adopted in order to reduce the error caused by non-uniformity of probe spacing. The measured electrical conductivity was found to decrease with increasing porosity ranging from 70% to 90% for the PMFSS produced under the same sintering condition. Our experimental results were found to agree well with the theoretical prediction by Liu’s model for the PMFSS with different porosities. The effect of sintering condition on electrical conductivity was also investigated. It was revealed that higher sintering temperature or longer holding time yields higher electrical conductivity of PMFSS.
Characterization of electrical conductivity of porous metal fiber sintered sheet using four-point probe method
Zhou, Wei (author) / Tang, Yong (author) / Song, Rong (author) / Jiang, Lelun (author) / Hui, K.S. (author) / Hui, K.N. (author)
2011-12-29
5 pages
Article (Journal)
Electronic Resource
English
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