[1] S DAS, S KUMAR, S K SAMAL et al. A review on superhydrophobic polymer nanocoatings: recent development and applications. Industrial & Engineering Chemistry Research, 57, 2727-2745(2018).

[2] B ATLE, J L S NORDVIK. Oil and water separation in marine oil spill clean-up operations. Spill Science & Technology Bulletin, 3, 107-122(1996).

[3] B TANSEL, J REGULA. Coagulation enhanced centrifugation for treatment of petroleum hydrocarbon contaminated waters. Journal of Environmental Science and Health, Part A, 35, 1557-1575(2000).

[4] L QIU, Y H SUN, Z G GUO. Designing novel superwetting surfaces for high-efficiency oil–water separation: design principles, opportunities, trends and challenges. Journal of Materials Chemistry A, 8, 16831-16853(2020).

[5] E GOGOLIDES, M VLACHOPOULOU, K TSOUGENI et al. Micro and nano structuring and texturing of polymers using plasma processes: potential manufacturing applications. International Journal of Nanomanufacturing, 6, 152-163(2010).

[6] A M EMELYANENKO, F M SHAGIEVA, A G DOMANTOVSKY et al. Nanosecond laser micro- and nanotexturing for the design of a superhydrophobic coating robust against long-term contact with water, cavitation, and abrasion. Applied Surface Science, 332, 513-517(2015).

[7] W G JIRU, M R SANKAR, U S DIXIT. Laser surface alloying of copper, manganese, and magnesium with pure aluminum substrate. Journal of Materials Engineering and Performance, 25, 1172-1181(2016).

[8] Y B CAO, S X ZHI, H B QI et al. Evolution behavior of ex-situ NbC and properties of Fe-based laser clad coating. Optics & Laser Technology, 124, 1-8(2020).

[9] X Y JIAO, J WANG, C WANG et al. Effect of laser scanning speed on microstructure and wear properties of T15M cladding coating fabricated by laser cladding technology. Optics and Lasers in Engineering, 110, 163-171(2018).

[10] J H CHEN, D Guo, C Y HUANG. Fabrication of superhydrophobic copper mesh by depositing CuCl for oil/water separation. Materials Letters, 233, 328-331(2018).

[11] M R DORFMAN. Handbook of environmental degradation of materials, 405-422(2005).

[12] R BRIAN, H C YUEN, W B LEE. The processing of metal matrix composites-an overview. Journal of Materials Processing Technology, 63, 339-353(1997).

[13] V KUMAR, R RAKSHIT, A K DAS. Mechanical and tribological performance of fiber laser cladded h-BN + SS316 composite on SS316 surface. Journal of Materials Processing Technology, 278, 1-13(2020).

[14] Dongsheng JI, Rushu PENG. Experiential study on nitrogen containing duplex stainless steel coating of laser cladding. Mechanical Research and Application, 33, 88-90(2020).

[15] Liming WANG, Shanhai CONG, Mei HU等. Study on microstructure and properties of wc reinforced fe-based composite. Rare Metals and Cemented Carbides, 43, 22-29(2015).

[16] L DING, S S HU, X M QUAN et al. Effect of heat treatment on the microstructure and properties of VN alloy/Co-based composite coatings. Surface and Coatings Technology, 313, 355-360(2017).

[17] J L GAO, C Z WU, Y B HAO et al. Numerical simulation and experimental investigation on three-dimensional modelling of single-track geometry and temperature evolution by laser cladding. Optics & Laser Technology, 129, 1-11(2020).

[18] M HUSSAIN, V MANDAL, P K SINGH et al. Experimental study of microstructure, mechanical and tribological properties of cBN particulates SS316 alloy based MMCs fabricated by DMLS technique. Journal of Mechanical Science and Technology, 31, 2729-2737(2017).

[19] H YAN, A H WANG, X L ZHANG et al. Nd:YAG laser cladding Ni base alloy/nano-h-BN self-lubricating composite coatings. Materials Science and Technology, 26, 461-468(2013).

[20] A K RAI, B SRINIVASULU, C P PAUL et al. Development of thick SiC coating on thin wall tube of zircaloy-4 using laser based directed energy deposition technique. Surface and Coatings Technology, 398, 1-14(2020).

[21] Haibo LI, Tao LI, Xinlin WANG等. Study on the influence of the inclined substrate to the energy distribution of laser cladding. Applied Laser, 37, 333-339(2017).

[22] M J SONG, L S WU, J M LIU et al. Effects of laser cladding on crack resistance improvement for aluminum alloy used in aircraft skin. Optics & Laser Technology, 133, 1-12(2021).

[23] G J WEI, Z J WANG, X X ZHAO et al. A facile approach to fabricate superhydrophobic and corrosion resistant surface. Materials Research Express, 2, 015501(2014).

[24] Xin WANG, Yansheng YIN, Yingcai LIU等. Crystal structure and valence electron structure of α-Al₂O₃. Transactions of Nonferrous Metals Society of China, 18-23(2002).

[25] Xiaowen ZHANG. Foundation of solid material structure(1980).

[26] G Q XIN, C Y WU, H Y CAO et al. Superhydrophobic TC4 alloy surface fabricated by laser micro-scanning to reduce adhesion and drag resistance. Surface and Coatings Technology, 391, 1-10(2020).

[27] J H ZUO, Z H LIU, C L ZHOU et al. A durable superwetting clusters-inlayed mesh with high efficiency and flux for emulsion separation. Journal of Hazardous Materials, 403, 1-11(2021).

[28] P YU, Z X LIAN, J K XU et al. Fabrication of superhydrophilic and underwater superoleophobic metal mesh by laser treatment and its application. Materials Research Express, 5, 1-10(2018).

[29] R AGARWAL, R S DONDAPATI. Numerical investigation on hydrodynamic characteristics of two-phase flow with liquid hydrogen through cryogenic feed lines at terrestrial and microgravity. Applied Thermal Engineering, 173, 1-14(2020).

[30] F RAEISZADEH, E HAJIDAVALLOO, M BEHBAHANINEJAD et al. Modeling and simulation of downward vertical two-phase flow with pipe rotation. Chemical Engineering Research and Design, 137, 10-19(2018).

[31] Heng ZHANG, Fang LIN, Jianchun SUN等. CFD analysis of tunnel construction ventilation efect based on typical wal roughnes model. China Railway Science, 37, 58-65(2016).