[1] [1] Li Meiyan, Wang Yong, Han Bin, et al.. Microstructure and corrosion resistance of laser surface melting modified layer on high chrome steel[J]. Materials Protecition, 2010, 43(3): 61-65.

[2] [2] Shi Hualiang, Li Jiqiang, Jia Zhixin, et al.. Microstructure and properties of SKD61 die steel strengthened by biomimetic laser-remelting [J]. Materials for mechanical engineering, 2014, 38(8): 39-43.

[3] [3] Gong Renzheng, Fan Xiangfang, Hu wei, et al.. Influence of laser melting on microstructure and mechanical properties of high velocity oxy-fuel sprayed cemented carbide coatings[J]. Hot Working Technology, 2015, 40(4): 81-84.

[4] [4] Wang C, Zhou H, Liang N, et al.. Mechanical properties of several laser remelting processed steels with different unit spacings[J]. Applied Surface Science. 2014, 313: 333-340.

[5] [5] Deng Meng, Wang Yiqiang, Gu Yan, et al.. Microstructure and wear behavior of laser hardened gray cast iron guideway[J]. Chinese J Lasers, 2014, 41(4): 0403009.

[6] [6] Wang Zhitai, Lin Xin, Cao Yongqing, et al.. External cooling condition effects on formation of anomalous eutectic in Ni-Sn alloy by laser remelting[J]. Chinese J Lasers, 2014, 41(12): 1203006.

[7] [7] Yi Peng, Xu Pengyun, Yin Keping, et al.. Laser thermo-repairing process modeling and thermal response analysison gray cast iron surface [J]. Chinese J Lasers, 2013, 40(3): 0303007.

[8] [8] Zhang Z, Lin P, Cong D, et al.. The characteristics of treated zone processed by pulsed Nd-YAG laser surface remelting on hot work steel [J]. Optics & Laser Technology, 2014, 64: 227-234.

[9] [9] Chikarakara E, Naher S, Brabazon D. Process mapping of laser surface modification of AISI 316L stainless steel for biomedical applications [J]. Applied Physics a-Materials Science & Processing, 2010, 101(2): 367-371.

[10] [10] Liu Hongxi, Cai Chuanxiong, Jiang Yehua, et al.. Influence of alternative magnetic field on macro morpholoy and microstructure of laser cladding Fe-based composite coating[J]. Optics and Precision engineering, 2012, 20(11): 2402-2410.

[11] [11] Qin Lanyun, Yang Guang, Bian Hongyou, et al.. Experimental study on electromagnetic stirring laser metal deposition titanium alloy[J]. Chinese J Lasers, 2014, 41(3): 0303004.

[12] [12] Wang Wei, Li Qi, Yang Guang, et al.. Numerical simulation of electromagnetic flow, temperature field and flow field in laser molten pool with electromagnetic stirring[J]. Chinese J Lasers, 2015, 42(2): 0202007.

[13] [13] Gatzen M. Influence of low-frequency magnetic fields during laser beam welding of aluminium with filler wire[J]. Physics Procedia, 2012, 39: 56-66.

[14] [14] Gatzen M, Tang Z. CFD-based model for melt flow in laser beam welding of aluminium with coaxial magnetic field[J]. Physics Procedia, 2010, 5: 317-326.

[15] [15] Bachmann M, Avilov V, Gumenyuk A, et al.. About the influence of a steady magnetic field on weld pool dynamics in partial penetration high power laser beam welding of thick aluminium parts[J]. International Journal of Heat and Mass Transfer, 2013, 60: 309-321.

[16] [16] Bachmann M, Avilov V, Gumenyuk A, et al.. Experimental and numerical investigation of an electromagnetic weld pool support system for high power laser beam welding of austenitic stainless steel[J]. Journal of Materials Processing Technology, 2014, 214(3): 578-91.

[17] [17] Hu Yong, Chen Zhijun, Wang Liang, et al.. Numerical simulation of the static magnetic field regulation of the laser molten pool heat transfer and flow behavior[J]. Applied Laser, 2014, 34(6): 508-512.

[18] [18] Liu Huilin, Lei Yuxia, He Jiajian, et al.. Research status of laser surface melting technology and itsnumerical simulation[J]. Ordnance Material Science and Engineering, 2013, 36(4): 86-91.

[19] [19] Yi Peng, Liu Yancong, Shi Yongjun, et al.. Numerical simulation of surface iron laser melting behavior and temperature distribution[J]. Transactions of The China Welding Institution, 2011, 32(8): 81-84.

[20] [20] Han Tao, Wang Yong. FEM simulation of laser melting of CK45 steel[J]. Hot Working Technology, 2007, 36(16): 80-83.

[21] [21] Brent A D, Voller V R, Reid K J. Enthalpy-porosity technique for modeling convection-diffusion phase change: Application to the melting of a pure metal[J]. Numerical Heat Transfer Part B-fundamentals, 1988, 13(3): 297-318.