[1] LV J, SONG Y, JIANG L, et al. Bio-Inspired Strategies for Anti-Icing [J]. Acs Nano, 2014, 8(4): 3 152-3 169.
[2] JIANG S, DIAO Y, YANG H. Recent advances of bio-inspired anti-icing surfaces [J]. Advances in Colloid and Interface Science, 2022, 308: 102 756.
[3] 赵一鉴, 燕则翔, 苏建民,等. 仿生防冰表面研究进展 [J]. 表面技术, 2021, 50(10): 29-39.
ZHAO Y J, YAN Z X, SU J M, et al. Research Progress of Biomimetic Anti-Icing Surface [J]. Surface Technology, 2021, 50(10): 29-39.
[4] COBER S G, ISAAC G A. Characterization of Aircraft Icing Environments with Supercooled Large Drops for Application to Commercial Aircraft Certification [J]. Journal of Applied Meteorology and Climatology, 2012, 51(2): 265-284.
[5] LASHER-TRAPP S, ANDERSON-BEREZNICKI S, SHACKELFORD A, et al. An Investigation of the Influence of Droplet Number Concentration and Giant Aerosol Particles upon Supercooled Large Drop Formation in Wintertime Stratiform Clouds [J]. Journal of Applied Meteorology and Climatology, 2008, 47(10): 2 659-2 678.
[6] WANG J, ZHANG J, XIE F, et al. A study of snow accumulating on the bogie and the effects of deflectors on the de-icing performance in the bogie region of a high-speed train [J]. Cold Regions Science and Technology, 2018, 148: 121-130.
[7] 康 健. 路面冻粘和疏水防冰涂层研究进展 [J]. 内蒙古公路与运输, 2020(3): 24-28.
KANG J.Research Progress of Frozen adhesive and hydrophobic Anti-icing Coatings on pavement [J]. Highways & Transportation in Inner Mongolia, 2020(3): 24-28.
[8] 邢金慧, 楚振宇, 解绍锋. 高速铁路接触网防融冰技术研究 [J]. 电力电容器与无功补偿, 2022, 43(4): 36-43.
XING J H, CHU Z Y, XIE S F. Research on the Anti-ice Melting Technology of Catenary in High-speed Railway [J]. Power Capacitor & Reactive Power Compensation, 2022, 43(4): 36-43.
[9] FARZANEH M, KIERNICKI J. Flashover problems caused by ice buildup on insulators [J]. Ieee Electrical Insulation Magazine, 1995, 11(2): 5-17.
[10] 莫秋云, 王国强, 郭荣滨, 等. 风力发电机叶片覆冰状况及防冰除冰措施 [J]. 科学技术与工程, 2022, 22(21): 9 017-9 024.
MO Q Y, WANG G Q, GUO R B, et al. Wind Turbine Blade Icing Condition and Anti-ice Deicing Measures [J]. Science Technology and Engineering, 2022, 22(21): 9 017-9 024.
[11] 于洪明, 于良峰, 游慧鹏, 等. 风电叶片防冰除冰技术的研究进展 [J]. 材料导报, 2016, 30(增刊1): 220-251.
YU H M, YU L F, YOU H P, et al. Research and Development on Anti-icing and De-icing Technology of Wind Turbine Blade [J].Materials Reports, 2016, 30(S1): 220-251.
[12] THOMAS S K, CASSONI R P, MACARTHUR C D. Aircraft anti-icing and de-icing techniques and modeling [J]. Journal of Aircraft, 1996, 33(5): 841-854.
[13] 刘 晨, 丁德一, 李逸辰, 等. 防冰材料研究进展 [J]. 材料导报, 2022, 36(16): 262-268.
LIU C,DING D Y, Li Y C, et al. Research Progress of Anti-icing Materials [J]. Materials Reports, 2022, 36(16): 262-268.
[14] WAHLIN J, KLEIN-PASTE A. The effect of common de-icing chemicals on the hardness of compacted snow [J]. Cold Regions Science and Technology, 2015, 109: 28-32.
[15] HANNAT R, WEISS J, GARNIER F, et al. Application of the dual kriging method for the design of hot-air-based aircraft wing anti-icing system [J]. Engineering Applications of Computational Fluid Mechanics, 2014, 8(4): 530-548.
[16] SUNDEN B, WU Z. On icing and icing mitigation of wind turbine blades in cold climate [J]. Journal of Energy Resources Technology-Transactions of the Asme, 2015, 137(5): 051 203.
[17] PALACIOS J, SMITH E, ROSE J, et al. Instantaneous de-icing of freezer ice via ultrasonic actuation [J]. Aiaa Journal, 2011, 49(6): 1 158-1 167.
[18] 梁镇宇, 朱志成, 韩毅平, 等. 防冰材料研究进展及其在风电领域的应用 [J]. 化学通报, 2022, 85(4): 386-400.
LIANG Z Y, ZHU Z C, HAN Y P, et al. Research Progress of Anti-Icing Materials and Its Application Prospects in Wind Power [J]. Chemistry Bulletin, 2022, 85(4): 386-400.
[19] BROEREN A P, LEE S, CLARK C. Aerodynamic effects of anti-icing fluids on a thin high-performance wing section [J]. Journal of Aircraft, 2016, 53(2): 451-462.
[20] ZHOU L, LIU R, YI X. Research and development of anti-icing/deicing techniques for vessels: Review [J]. Ocean Engineering, 2022, 260: 112 008.
[21] YANG S, WU C, ZHAO G, et al. Condensation frosting and passive anti-frosting [J]. Cell Reports Physical Science, 2021, 2(7): 100 474.
[22] LIU M, WANG S, JIANG L. Nature-inspired superwettability systems [J]. Nature Reviews Materials, 2017, 2(7): 17 036.
[23] HUANG W, HUANG J, GUO Z, et al. Icephobic/anti-icing properties of superhydrophobic surfaces [J]. Advances in Colloid and Interface Science, 2022, 304: 102 658.
[24] 王永芳, 刘文龙, 于庆州,等. 机械表面超疏水防冰技术应用研究进展 [J]. 机床与液压, 2022, 50(9): 190-200.
WANG Y F, LIU W L, YU Q Z, et al. Research Progress on the Application of Superhydrophobic and Anti-icing Technology on Mechanical Surfaces [J]. Machine Tool & Hydraulics, 2022, 50(9): 190-200.
[25] YOUNG T. An essay on the cohesion of fluids[J]. Philosophical Transactions of the Royal Society of London, 1805,95:65-87.
[26] VOGLER E A. Structure and reactivity of water at biomaterial surfaces [J]. Advances in Colloid and Interface Science, 1998, 74: 69-117.
[27] WENZEL R N. Resistance of solid surfaces to wetting by water [J]. Industrial and Engineering Chemistry, 1936, 28(8): 988-994.
[28] TIAN Y, JIANG L. Wetting: intrinsically robust hydrophobicity [J]. Nature Material, 2013, 12(4): 291-292.
[29] CASSIE A, BAXTERr S. Wettability of porous surfaces [J]. Trans Faraday Soc, 1944,40: 546-551.
[30] BICO J, THIELE U, Quéré D. Wetting of textured surfaces [J]. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2002, 206: 41-46.
[31] MARMUR A. The Lotus Effect: Superhydrophobicity and Metastability [J]. Langmuir, 2004, 20: 3 517-3 519.
[32] JUNG S, TIWARI M K, DOAN N V, et al. Mechanism of supercooled droplet freezing on surfaces [J]. Nature Communications, 2012, 3: 615.
[33] CAVALIERI D J, MARKUS T, HALL D K, et al. Assessment of EOS aqua AMSR-E Arctic Sea ice concentrations using Landsat-7 and airborne microwave imagery [J]. Ieee Transactions on Geoscience and Remote Sensing, 2006, 44(11): 3 057-3 069.
[34] FU Q T, LIU E J, WILSON P, et al. Ice nucleation behaviour on sol-gel coatings with different surface energy and roughness [J]. Physical Chemistry Chemical Physics, 2015, 17(33): 21 492-21 500.
[35] GAO H, ROSE J L. Ice detection and classification on an aircraft wing with ultrasonic shear horizontal guided waves [J]. Ieee Transactions on Ultrasonics Ferroelectrics and Frequency Control, 2009, 56(2): 334-344.
[36] EBERLE P, TIWARI M K, MAITRA T, et al. Rational nanostructuring of surfaces for extraordinary icephobicity [J]. Nanoscale, 2014, 6(9): 4 874-4 881.
[37] ZHANG Z, LIU X Y. Control of ice nucleation: freezing and antifreeze strategies [J]. Chemical Society Reviews, 2018, 47(18): 7 116-7 139.
[38] KNIGHT C A. Structural biology-Adding to the antifreeze agenda [J]. Nature, 2000, 406(6 793): 249-251.
[39] LIU X Y. Interfacial effect of molecules on nucleation kinetics [J]. Journal of Physical Chemistry B, 2001, 105(47): 11 550-11 558.
[40] NELSON J. Heterogeneous two-dimensional nucleation and growth kinetics-Comment [J]. Journal of Chemical Physics, 1997, 107(23): 10 350.
[41] SCHUTZIUS T M, JUNG S, MAITRA T, et al. Physics of icing and rational design of surfaces with extraordinary icephobicity [J]. Langmuir, 2015, 31(17): 4 807-4 821.
[42] HEYDARI G, THORMANN E, JARN M, et al. Hydrophobic surfaces: topography effects on wetting by supercooled water and freezing delay [J]. Journal of Physical Chemistry C, 2013, 117(42): 21 752-21 762.
[43] JUNG S, DORRESTIJN M, RAPS D, et al. Are Superhydrophobic surfaces best for icephobicity? [J]. Langmuir, 2011, 27(6): 3 059-3 066.
[44] GUO P, ZHENG Y, WEN M, et al. Icephobic/anti-icing properties of micro/nanostructured surfaces [J]. Advanced Materials, 2012, 24(19): 2 642-2 648.
[45] YANG N, ZHANG G, LI B. Violation of Fourier's law and anomalous heat diffusion in silicon nanowires [J]. Nano Today, 2010, 5(2): 85-90.
[46] SOLTIS J, PALACIOS J, EDEN T, et al. Ice adhesion mechanisms of erosion-resistant coatings [J]. Aiaa Journal, 2015, 53(3): 654-662.
[47] RYZHKIN I A, PETRENKO V F. Physical mechanisms responsible for ice adhesion [J]. Journal of Physical Chemistry B, 1997, 101(32): 6 267-6 270.
[48] WILEN L A, WETTLAUFER J S, ELBAUM M, et al. Dispersion-force effects in interfacial premelting of ice [J]. Physical Review B, 1995, 52(16): 12 426-12 433.
[49] CHUBARENKO I. Physical processes behind interactions of microplastic particles with natural ice [J]. Environmental Research Communications, 2022, 4(1): 012 001.
[50] JI X, OTERKUS E. Physical mechanism of ice/structure interaction [J]. Journal of Glaciology, 2018, 64(244): 197-207.
[51] 沈一洲, 谢欣瑜, 陶 杰, 等. 超疏水防冰材料的理论基础与应用研究进展 [J]. 中国材料进展, 2022, 41(5): 388-397.
SHEN Y Z, XIE X Y, TAO J, et al. Review on Theoretical Foundations and Applications of Superhydrophobic Anti-Icing Materials [J]. Material China, 2022, 41(5): 388-397.
[52] MISHCHENKO L, HATTON B, BAHADUR V, et al. Design of ice-free nanostructured surfaces based on repulsion of impacting water droplets [J]. ACS Nano, 2010, 4(12): 7 699-7 707.
[53] LECLEAR S, LECLEAR J, ABHIJEET, et al. Drop impact on inclined superhydrophobic surfaces [J]. Journal of Colloid and Interface Science, 2016, 461: 114-121.
[54] HE M, WANG J, LI H, et al. Super-hydrophobic surfaces to condensed micro-droplets at temperatures below the freezing point retard ice/frost formation [J]. Soft Matter, 2011, 7(8): 3 993-4 000.
[55] CAO L, JONES A K, SIKKA V K, et al. Anti-Icing Superhydrophobic Coatings [J]. Langmuir, 2009, 25(21): 12 444-12 448.
[56] NOSONOVSKY M, HEJAZI V. Why Superhydrophobic Surfaces Are Not Always Icephobic [J]. ACS Nano, 2012, 6(10): 8 488-8 491.
[57] BOREYKO J B, SRIJANTO B R, NGUYEN T D, et al.Dynamic Defrosting on Nanostructured Superhydrophobic Surfaces [J]. Langmuir, 2013, 29(30): 9 516-9 524.
[58] CHEN J, LIU J, HE M, et al. Superhydrophobic surfaces cannot reduce ice adhesion [J]. Applied Physics Letters, 2012, 101(11):111 603.
[59] WANG S, LIU K, YAO X, et al. Bioinspired surfaces with superwettability: new insight on theory, design, and applications [J]. Chemical Review, 2015, 115(16): 8 230-8 293.
[60] ZHANG J, CHENG Y, YANG Q, et al. Research progress of femtosecond laser preparation of durable superhydrophobic surface and its application(invited)[J]. Acta Photonica Sinica, 2022, 51(7): 0 751 414.
[61] PAN R, ZHANG H, ZHONG M. Triple-scale superhydrophobic surface with excellent anti-icing and icephobic performance via ultrafast laser hybrid fabrication [J]. ACS Applied Materials & Interfaces, 2021, 13(1): 1 743-1 753.
[62] CHE C, TIA Z, LU X, et al. Micro-nano-nanowire triple structure-held pdms superhydrophobic surfaces for robust ultra-long-term icephobic performance [J]. ACS Applied Materials & Interfaces, 2022, 14(20): 23 973-23 982.
[63] WANG L, TIAN Z, JIANG G, et al. Spontaneous dewetting transitions of droplets during icing & melting cycle [J]. Nature Communications, 2022, 13(1): 378.
[64] WANG L, JIANG G, TIAN Z, et al. Superhydrophobic microstructures for better anti-icing performances: open-cell or closed-cell? [J]. Materials Horizons, 2023,10, 209-220.
[65] LIU K, YANG C, ZHANG S, et al. Laser direct writing of a multifunctional superhydrophobic composite strain sensor with excellent corrosion resistance and Anti-Icing/Deicing performance [J]. Materials & Design, 2022, 218: 110 689.
[66] ZHAO M, YANG F, ZHANG X, et al. Anti-icing performance of complex texture silicone rubber surface based on laser engraving [J]. Chinese Journal of Lasers-Zhongguo Jiguang, 2022, 49(10): 1 002 603.
[67] TANG L, WANG N, HAN Z, et al. Robust superhydrophobic surface with wrinkle-like structures on AZ31 alloy that repels viscous oil and investigations of the anti-icing property [J]. Colloids and Surfaces a-Physicochemical and Engineering Aspects, 2020, 594: 124 655.
[68] JIAN Y, GAO H, YAN Y. Fabrication of a micro/nanoscaled hierarchical structure surface on brass with anti-icing and self-cleaning properties [J]. New Journal of Chemistry, 2021, 45(35): 16 059-16 068.
[69] XU Z, QI H, CHENG Y, et al. Nanocoating: Anti-icing superamphiphobic surface on 1060 aluminum alloy mesh [J]. Applied Surface Science, 2019, 498: 143 827.
[70] SHEN Y, WANG G, TAO J, et al. Anti-icing performance of superhydrophobic texture surfaces depending on reference environments [J]. Advanced Materials Interfaces, 2017, 4(22): 1 700 836.
[71] CHU F, GAO S, ZHANG X, et al. Droplet re-icing characteristics on a superhydrophobic surface [J]. Applied Physics Letters, 2019, 115(7): 073 703.
[72] JIN M, SHEN Y, LUO X, et al. A combination structure of microblock and nanohair fabricated by chemical etching for excellent water repellency and icephobicity [J]. Applied Surface Science, 2018, 455: 883-890.
[73] JAFARI R, MENINI R, FARZANEH M. Superhydrophobic and icephobic surfaces prepared by RF-sputtered polytetrafluoroethylene coatings [J]. Applied Surface Science, 2010, 257(5): 1 540-1 543.
[74] SUN Y, LIU J, MING P, et al. Wire electrochemical etching of superhydrophobic 304 stainless steel surfaces based on high local current density with neutral electrolyte [J]. Applied Surface Science, 2022, 571: 151 269.
[75] LIU Z, ZHANG F, CHEN Y, et al. Electrochemical fabrication of superhydrophobic passive films on aeronautic steel surface [J]. Colloids and Surfaces A-Physicochemical and Engineering Aspects, 2019, 572: 317-325.
[76] SAJI V S. Superhydrophobic surfaces and coatings by electrochemical anodic oxidation and plasma electrolytic oxidation [J]. Advances in Colloid and Interface Science, 2020, 283: 102 245.
[77] SHAO Y, ZHAO J, FAN Y, et al. Shape memory superhydrophobic surface with switchable transition between "Lotus Effect" to "Rose Petal Effect" [J]. Chemical Engineering Journal, 2020, 382: 122 989.
[78] CHEN A, WANG Q, LI M, et al. Combined approach of compression molding and magnetic attraction to micropatterning of magnetic polydimethylsiloxane composite surfaces with excellent anti-icing/deicing performance [J]. ACS Applied Materials & Interfaces, 2021, 13(40): 48 153-48 162.
[79] 张 磊, 王 斐, 潘 蕾. CF/PEEK复合材料表面构筑微纳米结构及其防冰性能的研究 [J]. 航空制造技术, 2019, 62(17): 95-101.
ZHANG L, WANG F, PAN L. Fabricating Micro-Nano Structure on Surface of CF/PEEK Composite and Study on Its Anti-Icing Property [J]. Aeronautical Manufacturing Technology, 2019, 62(17): 95-101.
[80] XIE Z, WANG H, DENG Q, et al. Heat transfer characteristics of carbon-based photothermal superhydrophobic materials with thermal insulation micropores during anti-icing/deicing [J]. Journal of Physical Chemistry Letters, 2022,13(43): 10 237-10 244.
[81] YIN X, ZHANG Y, WANG D, et al. Integration of self-lubrication and near-infrared photothermogenesis for excellent anti-icing/deicing performance [J]. Advanced Functional Materials, 2015, 25(27): 4 237-4 245.
[82] WANG Q, SUN G, TONG Q, et al. Fluorine-free superhydrophobic coatings from polydimethylsiloxane for sustainable chemical engineering: Preparation methods and applications [J]. Chem Eng J, 2021, 426: 130 829.
[83] WANG N, TANG L, TONG W, et al. Fabrication of robust and scalable superhydrophobic surfaces and investigation of their anti-icing properties [J]. Materials & Design, 2018, 156: 320-328.
[84] WEI J, LI B, TIAN N, et al. Scalable robust superamphiphobic coatings enabled by self-similar structure, protective micro-skeleton, and adhesive for practical anti-icing of high-voltage transmission tower [J]. Advanced Functional Materials, 2022, 32(43): 2 206 014.
[85] FU K, LU C, LIU Y, et al. Mechanically robust, self-healing superhydrophobic anti-icing coatings based on a novel fluorinated polyurethane synthesized by a two-step thiol click reaction [J]. Chemical Engineering Journal, 2021, 404: 127 110.
[86] SHARIFI N, DOLATABADI A, PUGH M, et al. Anti-icing performance and durability of suspension plasma sprayed TiO2 coatings [J]. Cold Regions Science and Technology 2019, 159: 1-12.
[87] ZHU T, CHENG Y, HUANG J, et al. A transparent superhydrophobic coating with mechanochemical robustness for anti-icing, photocatalysis and self-cleaning [J]. Chemical Engineering Journal, 2020, 399: 125 746.
[88] ZUO Z, SONG X, LIAO R, et al. Understanding the anti-icing property of nanostructured superhydrophobic aluminum surface during glaze ice accretion [J]. International Journal of Heat and Mass Transfer, 2019, 133: 119-128.
[89] ZUO Z, LIAO R, SONG X, et al. Improving the anti-icing/frosting property of a nanostructured superhydrophobic surface by the optimum selection of a surface modifier [J]. RSC Advances, 2018, 8(36): 19 906-19 916.
[90] ZUO Z, LIAO R, ZHAO X, et al. Anti-frosting performance of superhydrophobic surface with ZnO nanorods [J]. Applied Thermal Engineering, 2017, 110: 39-48.
[91] LIU G, YUAN Y, ZHOU J, et al. Anti-frosting/anti-icing property of nano-ZnO superhydrophobic surface on Al alloy prepared by radio frequency magnetron sputtering [J]. Materials Research Express, 2020, 7(2): 026 401.
[92] 占彦龙, 李 文, 李 宏, 等. 溶胶凝胶法铝基超疏水表面的制备及其防覆冰性能 [J]. 材料保护, 2016, 49(增刊1): 5-7.
ZHAN Y L, LI W, LI H, et al.Preparation and anti-icing performance of aluminum-based superhydrophobic surface by sol-gel method [J]. Materials Protection, 2016, 49(S1): 5-7.
[93] WANG Z, YAO D, HE Z, et al. Fabrication of durable, chemically stable, self-healing superhydrophobic fabrics utilizing gellable fluorinated block copolymer for multifunctional applications [J]. ACS Applied Materials & Interfaces, 2022, 14(42): 48 106-48 122.
[94] SUN J, HE D, LI Q, et al. Wettability behavior and anti-icing property of superhydrophobic coating on HTV silicone rubber [J]. AIP Advances, 2020, 10(12): 125 102.
[95] ESHAGHI A. Fabrication of transparent silica-silica nanotube/PFTS nano-composite thin films with superhydrophobic, oleophobic, self-cleaning and anti-icing properties [J]. Optical and Quantum Electronics, 2020, 52(12): 516.
[96] LI X, YANG B, ZHANG Y, et al. A study on superhydrophobic coating in anti-icing of glass/porcelain insulator [J]. Journal of Sol-Gel Science and Technology, 2014, 69(2): 441-447.
[97] ZHU R, LIU M, HOU Y, et al. One-pot preparation of fluorine-free magnetic superhydrophobic particles for controllable liquid marbles and robust multifunctional coatings [J]. ACS Applied Materials & Interfaces, 2020, 12(14): 17 004-17 017.
[98] DARMANIN T, DE GIVENCHY ET, AMIGONI S, et al. Superhydrophobic surfaces by electrochemical processes [J]. Advanced Material, 2013, 25(10): 1 378-1 394.
[99] SHI K, DUAN X. Freezing delay of water droplets on metallic hydrophobic surfaces in a cold environment [J]. Applied Thermal Engineering, 2022, 216: 119 131.
[100]BRASSARD J D, SARKAR D K, PERRON J, et al. Nano-micro structured superhydrophobic zinc coating on steel for prevention of corrosion and ice adhesion [J]. Journal of Colloid and Interface Science, 2015, 447: 240-247.
[101]ZHANG B, LU S, XU W, et al. Controllable wettability and morphology of electrodeposited surfaces on zinc substrates [J]. Applied Surface Science, 2016, 360: 904-914.
[102]FAN Q, JI X, LAN Q, et al. An anti-icing copper-based superhydrophobic layer prepared by one-step electrodeposition in both cathode and anode [J]. Colloids and Surfaces -A Physicochemical and Engineering Aspects, 2022, 637: 128 220.
[103]JIANG J, SHEN Y, WANG Z, et al. Anti/de-icing performance of the one-step electrodeposited superhydrophobic surfaces: Role of surface polarity regulated by hydrocarbon radical length [J]. Chemical Engineering Journal, 2022, 431: 133 276.