[1] G WINDRED. Electrical contact resistance. Journal of the Franklin Institute, 231, 547-585(1941).
[2] R HOLM, E HOLM. Electric Contacts Handbook. Berlin: Springer(1958).
[3] V COSOVIC, A COSOVIC, N TALIJAN et al. State of the art and challenges in development of electrical contact materials in the light of the RoHS directive. Science of Sintering, 44, 245-253(2012).
[4] G SLADE P. Effect of high temperature on the release of heavy metals from AgCdO and AgSnO2 contacts. IEEE Transactions on Components, Hybrids, and Manufacturing Technology, 12, 5-15(1989).
[5] H SCHRODER K. Silver-metal oxides as contact materials. IEEE Transactions on Components, Hybrids, and Manufacturing Technology, 10, 127-134(1987).
[6] P WU C, Q YI D, J LI et al. Investigation on microstructure and performance of Ag/ZnO contact material. Journal of Alloys and Compounds, 457, 565-570(2008).
[7] L ZHOU X, C CAO J, C CHEN J et al. Micro-superplastic behavior of copper oxide in AgCuO composites. Rare Metal Materials and Engineering, 42, 2242-2244(2013).
[8] D WOJCIK-GRZYBEK, K FRYDMAN, P BORKOWSKI. The influence of the microstructure on the switching properties of Ag C, Ag-WC-C and Ag-WC contact materials. Archives of Metallurgy and Materials, 58, 1059-1065(2013).
[9] P WU C, Q YI D, W WENG et al. Arc erosion behavior of Ag/Ni electrical contact materials. Materials & Design, 85, 511-519(2015).
[10] W BARSOUM M. The M
[11] M SUN Z. Progress in research and development on MAX phases: a family of layered ternary compounds. International Materials Reviews, 56, 143-166(2011).
[12] M ZHANG, B TIAN W, G ZHANG P et al. Microstructure and properties of Ag-Ti3SiC2 contact materials prepared by pressureless sintering. International Journal of Minerals, Metallurgy, and Materials, 25, 810-816(2018).
[13] X DING J, B TIAN W, G ZHANG P et al. Arc erosion behavior of Ag/Ti3AlC2 electrical contact materials. Journal of Alloys and Compounds, 740, 669-676(2018).
[14] X DING J, B TIAN W, D WANG D et al. Corrosion and degradation mechanism of Ag/Ti3AlC2 composites under dynamic electric arc discharging. Corrosion Science, 156, 147-160(2019).
[15] D WANG D, B TIAN W, B MA A et al. Anisotropic properties of Ag/Ti3AlC2 electrical contact materials prepared by equal channel angular pressing. Journal of Alloys and Compounds, 784, 431-438(2019).
[16] M LIU M, L CHEN J, H CUI et al. Ag/Ti3AlC2 composites with high hardness, high strength and high conductivity. Materials Letters, 213, 269-273(2018).
[17] X DING J, B TIAN W, G ZHANG P et al. Preparation and arc erosion properties of Ag/Ti2SnC composites under electric arc discharging. Journal of Advanced Ceramics, 8, 90-101(2019).
[18] X DING J, B TIAN W, D WANG D et al. Microstructure evolution, oxidation behavior and corrosion mechanism of Ag/Ti2SnC composite during dynamic electric arc discharging. Journal of Alloys and Compounds, 785, 1086-1096(2019).
[19] F ZHU J, Q GAO J, F YANG J et al. Synthesis and microstructure of layered-ternary Ti2AlC ceramic by high energy milling and hot pressing. Materials Science and Engineering A, 490, 62-65(2008).
[20] L BAI Y, X ZHANG H, D HE X et al. Growth morphology and microstructural characterization of nonstoichiometric Ti2AlC bulk synthesized by self-propagating high temperature combustion synthesis with pseudo hot isostatic pressing. International Journal of Refractory Metals and Hard Materials, 45, 58-63(2014).
[21] B ZHOU W, C MEI B, Q ZHU J et al. Rapid synthesis of Ti2AlC by spark plasma sintering technique. Materials Letters, 59, 131-134(2005).
[22] Y LIANG B, Z WANG M, P LI X et al. Synthesis of Ti2AlC by laser- induced self-propagating high-temperature sintering. Journal of Alloys and Compounds, 501, L1-L3(2010).
[23] W LIU, Z BO T, P XIE Z et al. Fabrication of injection moulded translucent alumina ceramics
[24] L YEH C, G SHEN Y. Combustion synthesis of Ti3AlC2 from Ti/Al/C/TiC powder compacts. Journal of Alloys and Compounds, 466, 308-313(2008).
