[1] BORCHERS A, PIELER T. Programming pluripotent precursor cells derived from Xenopus embryos to generate specific tissues and organs[J]. Genes, 413(2010).

[2] SHEN C, KHONSARI M M, SPADAFORA M et al. Tribological performance of polyamide-imide seal ring under seawater lubrication[J]. Tribology Letters, 39(2016).

[3] SHANKAR S, KRISHNA KUMAR P. Frictional characteristics of diamond like carbon and tungsten carbide/carbon coated high carbon high chromium steel against carbon in dry sliding conformal contact for mechanical seals[J]. Mechanics & Industry, 115(2017).

[4] PEREIRA P, VILHENA L M, SACRAMENTO J et al. Tribological behaviour of different formulations of WC composites[J]. Wear, 204415(2022).

[5] YAO X M, WANG X J, LIU X J et al. Friction-wear properties and mechanism of hard facing pairs of SiC and WC.[J]. Journal of Inorganic Materials, 673(2019).

[6] CHEN Q, BAI S X, YE Y C. Highly thermal conductive silicon carbide ceramics matrix composites for thermal management: a review[J]. Journal of Inorganic Materials, 634(2023).

[7] RAMASUBRAMANIAN K, NIKHIL C, RAO S et al. Tribological behavior of diamond coated reaction-bonded silicon carbide under dry and seawater environment[J]. Surface and Coatings Technology, 130204(2024).

[8] GUO X Z, WANG R, ZHENG P et al. Pressureless sintering of multilayer graphene reinforced silicon carbide ceramics for mechanical seals[J]. Advances in Applied Ceramics, 409(2019).

[9] CAI N N, GUO D D, WU G P et al. Decreasing resistivity of silicon carbide ceramics by incorporation of graphene[J]. Materials, 3586(2020).

[10] DIAO Q W, ZOU H B, REN X Y et al. A focused review on the tribological behavior of C/SiC composites: present status and future prospects[J]. Journal of the European Ceramic Society, 3875(2023).

[11] ZHANG W, YAMASHITA S, KITA H. Progress in tribological research of SiC ceramics in unlubricated sliding-a review[J]. Materials & Design, 108528(2020).

[12] ZHANG W. Tribology of SiC ceramics under lubrication: features, developments, and perspectives[J]. Current Opinion in Solid State and Materials Science, 101000(2022).

[13] YAMAMOTO Y, URA A. Influence of interposed wear particles on the wear and friction of silicon carbide in different dry atmospheres[J]. Wear, 141(1992).

[14] PRESSER V, KRUMMHAUER O, NICKEL K G et al. Tribological and hydrothermal behaviour of silicon carbide under water lubrication[J]. Wear, 771(2009).

[15] MATSUDA M, KATO K, HASHIMOTO A. Friction and wear properties of silicon carbide in water from different sources[J]. Tribology Letters, 33(2011).

[16] REN P W, MENG H M, XIA Q J et al. Tribocorrosion of 316L stainless steel by in situ electrochemical methods under deep-sea high hydrostatic pressure environment[J]. Corrosion Science, 110315(2022).

[17] REN P W, MENG H M, XIA Q J et al. Influence of seawater depth and electrode potential on the tribocorrosion of Ti6Al4V alloy under the simulated deep-sea environment by in situ electrochemical technique[J]. Corrosion Science, 109185(2021).

[18] REN P W, MENG H M, XIA Q J et al. Study on the tribocorrosion behavior of Cu-Ni-Zn alloy in deep-sea environment by in situ electrochemical method[J]. Wear, 204594(2023).

[19] VERICHEV S N, MISHAKIN V V, NUZHDIN D A et al. Experimental study of abrasive wear of structural materials under the high hydrostatic pressure[J]. Ocean Engineering, 9(2015).

[20] MISHAKIN V V, VERICHEV S N, RAZOV E N. Investigation of the influence of high hydrostatic pressure on the abrasive wear of hard-alloy materials[J]. Journal of Friction and Wear, 286(2017).

[21] WANG J Z, CHEN J, CHEN B B et al. Wear behaviors and wear mechanisms of several alloys under simulated deep-sea environment covering seawater hydrostatic pressure[J]. Tribology International, 38(2012).

[22] WANG L J, QIAO Z H, QI Q et al. Improving abrasive wear resistance of Si₃N₄ ceramics with self-matching through tungsten induced tribochemical wear[J]. Wear, 204254(2022).

[23] FENG D, QIN Z B, REN Q X et al. Occurrence forms of major impurity elements in silicon carbide[J]. Ceramics International, 205(2022).

[24] XIANG D D, HE Q C, LAN D et al. Regulating the phase composition and microstructure of Fe₃Si/SiC nanofiber composites to enhance electromagnetic wave absorption[J]. Chemical Engineering Journal, 155406(2024).

[25] KIM W, LIM S H, HONG H et al. Optimum boundaries for maximum load-carrying capacity in water-lubricated composite journal bearings incorporating turbulences and inertial effects based on elastohydrodynamic analysis[J]. Journal of Computational Design and Engineering, 2506(2022).

[26] ZHANG X L, YIN Z W, JIANG D et al. The design of hydrodynamic water-lubricated step thrust bearings using CFD method[J]. Mechanics & Industry, 197(2014).

[27] WANG X L, ADACHI K, OTSUKA K et al. Optimization of the surface texture for silicon carbide sliding in water[J]. Applied Surface Science, 1282(2006).