[1] Xie Z H, Zeng F W, Xiao J B. Properties and research progress of silicone rubber[J]. Special Purpose Rubber Products, 32, 69-72(2011).

[2] Yang J. Application of silicone materials in aviation industry[J]. Chemical Engineering Design Communications, 45, 64-96(2019).

[3] Peng L. Application of silicone rubber in external insulation of power system[J]. Telecom Power Technology, 36, 23-24(2019).

[4] Wang L, Gong Q H, Zhan S H et al. Robust anti-icing performance of a flexible superhydrophobic surface[J]. Advanced Materials, 28, 7729-7735(2016). http://europepmc.org/abstract/MED/27375270

[5] Shao J, Zhao Y M, Yang C L. Properties of silicone rubber of insulator and its application in high voltage transmission line[J]. High Voltage Apparatus, 45, 155-158(2009).

[6] Seyedmehdi S A, Zhang H, Zhu J. Superhydrophobic RTV silicone rubber insulator coatings[J]. Applied Surface Science, 258, 2972-2976(2012).

[7] Gao S H, Zhou E Z. Hydrophobic modification on the surface of silicone rubber insulator by CF4 RF plasma[J]. Polymer Materials Science & Engineering, 29, 101-104,109(2013).

[8] Lin C, Zhong M L, Fan P X et al. Picosecond laser fabrication of large-area surface micro-nano lotus-leaf structures and replication of superhydrophobic silicone rubber surfaces[J]. Chinese Journal of Lasers, 41, 0903007(2014).

[9] Zhou P Y, Peng Y Z, Huang Z M et al. Fabrication and droplet impact performance of superhydrophobic surfaces developed using nanosecond lasers[J]. Chinese Journal of Lasers, 47, 0402012(2020).

[10] Fang Y, Yong J L, Chen F et al. Bioinspired fabrication of bi/tridirectionally anisotropic sliding superhydrophobic PDMS surfaces by femtosecond laser[J]. Advanced Materials Interfaces, 5, 1701245(2018). http://onlinelibrary.wiley.com/doi/abs/10.1002/admi.201701245

[11] Yang H, Xu K C, Xu C W et al. Femtosecond laser fabricated elastomeric superhydrophobic surface with stretching-enhanced water repellency[J]. Nanoscale Research Letters, 14, 1-10(2019).

[12] Chen L, Wang X, Yang T et al. Superhydrophobic micro-nano structures on silicone rubber by nanosecond laser processing[J]. Journal of Physics D: Applied Physics, 51, 445301(2018). http://www.researchgate.net/publication/327639432_Superhydrophobic_micro-nano_structures_on_silicone_rubber_by_nanosecond_laser_processing

[13] Qu A L, Cheng J, Yang Z R. Hydrophobicity on film surfaces with composite particles estimated by fractal theory[J]. Chinese Journal of Inorganic Chemistry, 26, 615-620(2010).

[14] Yadav R P, Kumar T, Baranwal V et al. Fractal characterization and wettability of ion treated silicon surfaces[J]. Journal of Applied Physics, 121, 055301(2017).

[15] Li X B, Liu Y. Control and prepartion to wettability of material surfaces[J]. Journal of Materials Engineering, 36, 74-80(2008).

[16] Ge S R, Suo S F. The computation methods for the fractal dimension of surface profiles[J]. Tribology, 17, 354-362(1997).

[17] Zhong L, Zeng F, Xu G X. Comparison of fractal dimension calculation methods for channel bed profiles[J]. Procedia Engineering, 28, 252-257(2012).

[18] Yuan C Q, Li J, Yan X P et al. The use of the fractal description to characterize engineering surfaces and wear particles[J]. Wear, 255, 315-326(2003). http://www.sciencedirect.com/science/article/pii/S0043164803002060