[1] [1] J. R. Davis. ASM Specialty Handbook: Copper and Copper Alloys ［M］. Materials Park: ASM International, 2001. 153～168

[2] [2] K. P. Cooper, H. N. Jones, R. A. Meger. Analysis of railgun barrel material ［J］. IEEE Transactions on Magnetics, 2007, 43(1):120～125

[3] [3] G. L. Jackson, L. K. Farris, M. M. Tower. Electromagnetic railgun extended-life bore material tests results ［J］. IEEE Transactions on Magnetics, 1986, 22(6):1542～1545

[4] [4] S. N. Rosenwasser. Recent advances in large railgun structures and materials technology ［J］. IEEE Transactions on Magnetics, 1991, 27(1):444～451

[5] [5] D. P. Bauer, J. M. Juston. Rapid testing for multishot railgun bore life ［J］. IEEE Transactions on Magnetics, 1997, 33(1):390～394

[6] [6] R. M. Gee, C. Persad. The response of different copper alloys as rail contacts at the breech of an electromagnetic launcher ［J］. IEEE Transactions on Magnetics, 2001, 37(1):263～269

[7] [7] R. A. Meger, K. Cooper, H. Jones et al.. Analysis of rail surfaces from a multishot railgun ［J］. IEEE Transactions on Magnetics, 2005, 41(1):211～213

[8] [8] A. Bell, H. A. Davis. Solid solubility extension in Cu-V and Cu-Cr alloys produced by chill block melt-spinning ［J］. Materials Science and Engineering A, 1997, 226-228:1039～1041

[9] [9] F. Lopez, J. Reyes, B. Campillo et al.. Rapid solidification of copper alloys with high strength and high conductivity ［J］. Journal of Materials Engineering and Performance, 1997, 6(5):611～614

[10] [10] G. Dehm, B. Medres, L. Shepeleva et al.. Microstructure and tribological properties of Ni-based claddings on Cu substrates ［J］. Wear, 1999, 225-229(Part 1):18～26

[11] [11] Yongzhong Zhang, Yi Tu, Mingzhe Xi et al.. Characterization on laser clad nickel based alloy coating on pure copper ［J］. Surface & Coatings Technology, 2008, 202(24):5924～5928

[12] [12] Fang Liu, Changsheng Liu, Suiyuan Chen et al.. Laser cladding Ni-Co duplex coating on copper substrate ［J］. Optics and Lasers in Engineering, 2010, 48(7-8):792～799

[13] [13] Hua Yan, Aihua Wang, Kaidong Xu et al.. Microstructure and interfacial evaluation of Co-based alloy coating on copper by pulsed Nd∶YAG multilayer laser cladding ［J］. Journal of Alloys and Compounds, 2010, 505(2):645～653

[14] [14] Chen Suiyuan, Dong Jiang, Liu Daliang et al.. Ceramic particle reinforce Co-based alloy gradient coating by laser synthesis in-situ on the surface of Cu-Cr alloy ［J］. Chinese J. Lasers, 2009, 36(5):1218～1223

[15] [15] K. W. Ng, H. C. Man, F. T. Cheng et al.. Laser cladding of copper with molybdenum for wear resistance enhancement in electrical contacts ［J］. Applied Surface Science, 2007, 253(14):6236～6241

[16] [16] Dong Jiang, Chen Suiyuan, Liu Daliang et al.. Structure and mechanism of Co-based alloy coating with laser inducing in-situ synthesis on the surface of copper alloy ［J］. Chinese J. Lasers, 2009, 36(5):1302～1307

[17] [17] Mingju Chao, Wenli Wang, Erjun Liang et al.. Microstructure and wear resistance of TaC reinforced Ni-based coating by laser cladding ［J］. Surface & Coatings Technology, 2008, 202(10):1918～1922

[18] [18] Jing Xiaoding, Chao Mingju, Sun Haiqin et al.. Investigation on in-situ synthesis of Cr3C2-CrB reinforced Ni-based composite coatings by laser cladding ［J］. Chinese J. Lasers, 2009, 36(1):231～237

[19] [19] National Standardization Technical Committee. Test Methods for Electrical Properties of Electric Cables and Wires—Part 2: Test of Electrical Resistivity of Metallic Materials. GB/T 3048.2-2007 ［S］. Beijing: China Standard Press, 2007

[20] [20] Zhou Shengfeng, Zeng Xiaoyan. Analysis of related factors to affect WC ceramic-metal composite coatings prepared by laser induction hybrid rapid cladding ［J］. Chinese J. Lasers, 2010, 37(5):1380～1385

[21] [21] H. T. Zhou, J. W. Zhong, X. Zhou et al.. Microstructure and properties of Cu-1.0Cr-0.2Zr-0.03Fe alloy ［J］. Materials Science and Engineering A, 2008, 498(1-2):225～230

[22] [22] S. G. Mu, F. A. Guo, Y. Q. Tang et al.. Study on microstructure and properties of aged Cu-Cr-Zr-Mg-RE alloy ［J］. Materials Science and Engineering A, 2008, 475(1-2):235～240

[23] [23] R. A. Espinoza, R.H. Palma, A.O. Sepulveda et al.. Microstructural characterization of dispersion-strengthened Cu-Ti-Al alloys obtained by reaction milling ［J］. Materials Science and Engineering A, 2007, 454-455:183～193

[24] [24] GlidCop Technical Data Sheet: http://www.spotweldingconsultants.com/glidcop.htm ［OL］. 2011-2-25