Ultrahigh Oxidation Resistance and High Electrical Conductivity in Copper-Silver Powder

Li, Jiaxiang; Li, Yunping; Wang, Zhongchang; Bian, Huakang; Hou, Yingwei; Wang, Fenglin; Gong, Xu; Liu, Bin; Liu, Yong

doi:10.1038/srep39650

Cited by 53 publications

(19 citation statements)

References 31 publications

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“…39) The WCu composites fabricated by activated sintering process have low electron and conductivity due to that the activated elements go into solution with Cu and decrease electrical conductivity significantly. 40,41) However, the Ag was separated out from the CuAg solid solution and formed a new phase with single Ag element when cooling process in this study, which is coincide with the reports of Li et al 37) The Ag distributed in boundaries and filled the pores in the W-rich area forming a continuous CuAg network along W-boundaries improved the interface and caused densification of the composites, which is the reason that the electrical conductivity of W 18Cu2Ag is higher than W20Ag composite.…”

Section: Sintering Behaviorsupporting

confidence: 91%

“…8), Ag is able to dissolve completely into Cu matrix at high temperature while most of Ag will precipitate from Cu matrix during the subsequent cooling, according to CuAg Phase Diagram 36) and our previous research. 37) During liquid sintering process, Ag dissolved in liquid Cu, which is considered to enhance the wettability between liquid Cu and W. The higher capillary force caused by higher wettability and higher wetting speed of liquid CuAg phase to W than liquid Cu resulted in densification of the composites. During cooling process, Ag was preferentially precipitated from the Cu and uniformly distributed in the crystal boundaries and locations of voids with the temperature decreasing, which caused further densification of the composites.…”

Section: Sintering Behaviormentioning

confidence: 99%

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Enhanced Property of W–Cu Composites by Minor Addition of Ag

Gong

et al. 2019

Mater. Trans.

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Nano-scale W20Cu (mass%) and W18Cu2Ag (mass%) composite powders were obtained by mechano-thermochemical process, followed by liquid phase sintering process from 1200 to 1300°C. The results indicate that the relative density and electrical conductivity of W18Cu2Ag composite were much superior to the W20Cu composite at all temperatures. Microstructural investigation reveals that minor addition of Ag is beneficial to the densification of WCu composite. This can be ascribed to the stronger the wettability and capillary force of liquid CuAg to W compared to that of pure Cu. Furthermore, during cooling Ag can precipitate into the voids between the W particles in W-rich area where is hard to be infiltrated by liquid Cu at high temperature, which is also beneficial to electrical conductivity.

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Section: Sintering Behaviorsupporting

confidence: 91%

Section: Sintering Behaviormentioning

confidence: 99%

Enhanced Property of W–Cu Composites by Minor Addition of Ag

Gong

et al. 2019

Mater. Trans.

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“…The second and third factors result in a reduction in electrical conductivity by causing pores to form in the microstructure. In addition to these factors, elements found in copper metal, such as C and O, may tend to enhance the scattering rate of conducting electrons, resulting in a reduction in the electrical conductivity of the copper (Li et al, 2016;Ayyapadas et al, 2017;Degroh and Balachandran, 2018). Although the amount of Fe, Cr, and Ni contaminants in this study was insufficient to alter the electrical conductivity, C and O may have had a modest effect on the reduction of electrical resistance.…”

Section: Electrical Conductivitymentioning

confidence: 99%

Comparison of the effects of microwave and spark plasma sintering on the electrical, thermal, and mechanical properties of Cu-LaB6 nanocomposites

Diler¹

2021

Gümüşhane Üniversitesi Fen Bilimleri Enstitüsü Dergisi

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The effects of lanthanum hexaboride (LaB6) nano-particles on the electrical, thermal, and mechanical properties of copper-based nanocomposites (Cu-LaB6) produced using microwave sintering (MS) and spark plasma sintering (SPS) processes were investigated in this study. Nano LaB6 particles reduced the electrical conductivity of Cu matrix nanocomposites produced via MS and SPS by 20% and 13%, respectively. Cu-LaB6 nanocomposites had lower thermal conductivity than unreinforced Cu. The electrical and thermal conductivities of the Cu-LaB6 nanocomposite produced by the SPS process were higher than those of the Cu-LaB6 nanocomposite produced by the MS process. An equation that takes particle volume ratio and porosity into account was developed to predict the thermal conductivity of nanocomposites from their electrical conductivity. The calculated thermal conductivity values for Cu-LaB6 nanocomposites were very close to the experimental results. Cu-LaB6 nanocomposites had much higher hardness and compressive strength by 49% and 38%, respectively, compared to those of unreinforced Cu. The hardness and compressive strength of the Cu-LaB6 nanocomposite produced by SPS were higher than those of the Cu-LaB6 nanocomposite manufactured via MS. Although nano LaB6 reinforcement particles reduced the electrical and thermal conductivities of Cu, Cu-LaB6 nanocomposite having high hardness and compressive strength were produced by combining the positive influences of nano LaB6 reinforcement particles and the SPS process.

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“…The invented technique involves copper-containing particles being encapsulated by additional layers of metal and alloys to restrict oxidation and diffusion of copper during the firing. For improving the oxidation resistance of copper, alloying copper with other metals (Ti, Mg, Al, Pd, Ag, Ni, Cr, and Zr) has been researched [37][38][39][40]. The Cu-Ag alloy is estimated as the best materials for improving oxidation resistance with only a slight reduction in electrical conductivity [41].…”

Section: Copper Paste For High-temperature Annealing (Firing Type)mentioning

confidence: 99%

Conductive Copper Paste for Crystalline Silicon Solar Cells

Lee¹,

Lee²

2019

Recent Developments in Photovoltaic Materials and Devices

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In photovoltaic industries, the main technique of metallization is screen printing with silver pastes due to its simple and quick process. However, the expensive price of silver paste is one of the barriers to the production of low-cost solar cells. Therefore, the most focused target in photovoltaic research is the decreasing consumption of silver paste or substitute silver for other materials. As a proper candidate, copper has been researched by many institutes and companies since it has a similar conductivity with silver even though the price is inexpensive. To apply copper as a contact for solar cells, the plating technique has been actively researched. However, copper paste, which was mainly developed for integrated circuit applications, has been recently researched. Mostly, copper paste was developed for the low-temperature annealing process since copper tends to oxidize easily. On the other hand, firing type copper paste was also developed by coating copper particles with a barrier layer. This chapter discusses recent development of copper paste for the application of solar cells and its appropriate annealing conditions for better electrical properties. Also, the light I-V characteristics of copper paste on the solar cells in other research papers are summarized as well.

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Ultrahigh Oxidation Resistance and High Electrical Conductivity in Copper-Silver Powder

Cited by 53 publications

References 31 publications

Enhanced Property of W–Cu Composites by Minor Addition of Ag

Enhanced Property of W–Cu Composites by Minor Addition of Ag

Comparison of the effects of microwave and spark plasma sintering on the electrical, thermal, and mechanical properties of Cu-LaB6 nanocomposites

Conductive Copper Paste for Crystalline Silicon Solar Cells

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