[1] [1] Upadhyaya A, Sarathy D, Wagner G. Advances in sintering of hard metals［J］. Materials & Design, 2001, 22(6): 499-506.

[2] [2] Engqvist H, Jacobson S, Axén N. A model for the hardness of cemented carbides［J］. Wear, 2002, 252(5/6): 384-393.

[3] [3] Li Y S, Deng J X, Zhang H, et al. Oxidation resistance of cemented carbide tools［J］. Journal of Materials Engineering, 2009, 37(2): 34-37.

[4] [4] Hao X Q, Song X L, Li L. Development and perspective of surface texturing tools［J］. Surface Technology, 2016, 45(9): 170-181.

[5] [5] Wang Z, Li L, Qi B Y, et al. Effect of micro-texture on surface frictional properties of cemented carbide［J］. Tool Engineering, 2011, 45(1): 13-16.

[6] [6] Obikawa T, Kamio A, Takaoka H, et al. Micro-texture at the coated tool face for high performance cutting［J］. International Journal of Machine Tool and Manufacture, 2011, 51(12): 966-972.

[7] [7] Pettersson U, Jacobson S. Textured surfaces in sliding boundary lubricated contacts-mechanisms, possibilities and limitations［J］. Tribology-Materials, Surfaces & Interfaces, 2007, 1(4): 181-189.

[8] [8] Borghi A,Gualtieri E,Marchetto D, et al. Tribological effects of surface texturing on nitriding steel for high-performance engine applications［J］. Wear, 2008, 265(7/8): 1046-1051.

[9] [9] Meng F M, Zhou R, Davis T, et al. Study on effect of dimples on friction of parallel surfaces under different sliding conditions［J］. Applied Surface Science, 2010, 256(9): 2863-2875.

[10] [10] Wu Z, Deng J X, Xing Y Q, et al. Effect of surface texturing on friction properties of WC/Co cemented carbide［J］. Materials & Design, 2012, 41: 142-149.

[11] [11] Sugihara T, Enomoto T. Development of a cutting tool with a nano/micro-textured surface—Improvement of anti-adhesive effect by considering the texture patterns［J］. Precision Engineering, 2009, 33(4): 425-429.

[12] [12] Kawasegi N, Sugimori H, Morimoto H, et al. Development of cutting tools with microscale and nanoscale textures to improve frictional behavior［J］. Precision Engineering, 2009, 33(3): 248-254.

[13] [13] Chen Y K, Melvin L S, Rodriguez S, et al. Capillary driven flow inmicro scale surface structures［J］. Microelectronic Engineering, 2009, 86(4/5/6): 1317-1320.

[14] [14] Zhang J X, Yao Z H, Hao P F, et al. Study of preparation and dynamic hydrophobicity of superhydrophobic surfaces with micro-nano textures［J］. Applied Mathematics and Mechanics, 2014, 35(3): 322-330.

[15] [15] Xiong Q Y, Dong L, Jiao Y L, et al. Wettability of surfaces with different surface microstructures textured by laser［J］. Acta Physica Sinica, 2015, 64(20): 206101.

[16] [16] Yang Q B, Xiao C G, Chen Z P, et al. Surface wettability of laser-induced Al2O3 ceramic tools［J］. Laser & Optoelectronics Progress, 2017, 54(10): 101401.

[17] [17] Feng A X, Yang R, Shi F, et al. Wettability of laser micro-textured carbide surface［J］. High Power Laser and Particle Beams, 2014, 26(2): 305-308.

[18] [18] Long J Y, Fan P X, Gong D W, et al. Ultrafast laser fabricated bio-inspired surfaces with special wettability［J］. Chinese Journal of Lasers, 2016, 43(8): 0800001.

[19] [19] Gu L, Sun H L, Yu K, et al. Research progress of micro-nanofabrication by femtosecond laser［J］. Laser & Infrared, 2013, 43(1): 14-18.

[20] [20] He F, Cheng Y. Femtosecond laser micromachining: Frontier in laser precision micromachining［J］. Chinese Journal of Lasers, 2007, 34(5): 595-622.

[21] [21] Lu J Z, Sun J N. Metal cutting theory and cutting tools［M］. 5th ed. Beijing: China Machine Press, 2011: 29-33.

[22] [22] Wenzel R N. Resistance of solid surfaces to wetting by water［J］. Industrial & Engineering Chemistry, 1936, 28(8): 988-994.

[23] [23] Cassie A B D. Contact angles［J］. Discussions of the Faraday Society, 1948, 3: 11-16.

[24] [24] Cheng S, Dong Y K, Zhang X J. Study of the influence of apparent contact angle on regular rough surface considering liquid wetting properties［J］. Mechanical Science and Technology for Aerospace Engineering, 2007, 26(7): 822-827.