[1] S LI, X ZENG, H CHEN et al. Porous hexagonal boron nitride nanosheets from g-C3N4 templates with a high specific surface area for CO2 adsorption. Ceramics International, 46, 27627-27633(2020).
[2] S SARAVANAN, R K CHIDAMBARAM, V E GEO. An experimental study to analyze influence of porous media combustor on performance and emission characteristics of a DI diesel engine. Fuel, 280, 118645-1-8(2020).
[3] K BICY, N KALARIKKAL, A M STEPHEN et al. Facile fabrication of microporous polypropylene membrane separator for lithium-ion batteries. Materials Chemistry and Physics, 255, 123473-1-9(2020).
[4] B PAN, J CHEN, F ZHANG et al. Porous TiO2 aerogel-modified SiC ceramic membrane supported MnOx catalyst for simultaneous removal of NO and dust. Journal of Membrane Science, 611, 118366-1-10(2020).
[5] X SONG, B JIAN, J JIN. Preparation of porous ceramic membrane for gas-solid separation. Ceramics International, 44, 20361-20366(2018).
[6] Z WANG, Z PAN. Preparation of hierarchical structured nano-sized/ porous poly (lactic acid) composite fibrous membranes for air filtration. Applied Surface Science, 356, 1168-1179(2015).
[7] X LIU, C L MARTIN, D BOUVARD et al. Strength of highly porous ceramic electrodes. Journal of the American Ceramic Society, 94, 3500-3508(2011).
[8] W HUO, X ZHANG, Y CHEN et al. Mechanical strength of highly porous ceramic foams with thin and lamellate cell wall from particle-stabilized foams. Ceramics International, 44, 5780-5784(2018).
[9] M L SAUCEDO, T LOWE, S ZHAO et al. In situ observation of mechanical damage within a SiC-SiC ceramic matrix composite. Journal of Nuclear Materials, 481, 13-23(2016).
[10] C SONG, X LIU, F YE et al. Mechanical and dielectric properties of SiCf/BN/SiBCN composites via different synthesis technologies. Journal of the European Ceramic Society, 39, 4417-4423(2019).
[11] H WANG, X ZHOU, J YU et al. Fabrication of SiCf/SiC composites by chemical vapor infiltration and vapor silicon infiltration. Materials Letters, 64, 1691-1693(2010).
[12] E W WONG, P E SHEEHAN, C M LIEBER. Nanobeam mechanics: elasticity, strength, and toughness of nanorods and nanotubes. Science, 277, 1971-1975(1997).
[13] Y ZHANG, X HAN, K ZHENG et al. Direct observation of super- plasticity of beta-SiC nanowires at low temperature. Advanced Functional Materials, 17, 3435-3440(2007).
[14] S R C VIVEKCHAND, U RAMAMURTY, C N R RAO. Mechanical properties of inorganic nanowire reinforced polymer-matrix composites. Nanotechnology, 17, 344-S350(2006).
[15] L XIN, W YANG, Q ZHAO et al. Strengthening behavior in SiC nanowires reinforced pure Al composite. Journal of Alloys and Compounds, 695, 2406-2412(2017).
[16] Q L SHEN, H J LI, L LI et al. SiC nanowire reinforced carbon/ carbon composites with improved interlaminar strength. Materials Science and Engineering: A, 651, 583-589(2016).
[17] L H DONG, H J ZHANG, J ZHANG et al. Carbon nanotube modified sepiolite porous ceramics for high-efficient oil/water separation. Journal of Inorganic Materials, 35, 689-696(2020).
[18] K J ZHANG, A YADAV, K H KIM et al. Thermal and electrical transport in ultralow density single-walled carbon nanotube networks. Advanced Materials, 25, 2926-2931(2013).
[19] X ZHAO, C HUANG, Q LIU et al. Thermal conductivity model for nanofiber networks. Journal of Applied Physics, 123, 085103-1-10(2018).
[20] R MA, X CHENG, W YE. SiC fiber and yttria-stabilized zirconia composite thick thermal barrier coatings fabricated by plasma spray. Applied Surface Science, 357, 407-412(2015).
[21] L ZHUANG, Q G FU, T Y LIU et al. In-situ PIP-SiC NWs- toughened SiC-CrSi2-Cr3C2-MoSi2-Mo2C coating for oxidation protection of carbon/carbon composites. Journal of Alloys and Compounds, 675, 348-354(2016).
[22] Y CHU, H LI, Q FU et al. Toughening by SiC nanowires in a dense SiC-Si ceramic coating for oxidation protection of C/C composites. Journal of the American Ceramic Society, 95, 3691-3697(2012).
[23] D WANG, C XUE, H BAI et al. Silicon carbide nanowires grown on graphene sheets. Ceramics International, 41, 5473-5477(2015).
[24] V H NGUYEN, S A DELBARI, Z AHMADI et al. Electron microscopy characterization of porous ZrB2-SiC-AlN composites prepared by pressureless sintering. Ceramics International, 46, 25415-25423(2020).
[25] X LI, D YAO, K ZUO et al. Microstructure and permeability of porous YSZ ceramics fabricated by freeze casting of oil-in-water suspension. Journal of the European Ceramic Society, 40, 5845-5851(2020).
[26] E FITZER, D HEGEN. Chemical vapor-deposition of silicon- carbide and silicon-nitride-chemistrys contribution to modern silicon ceramics. Angewandte ChemieInternational Edition, 18, 295-304(1979).
[27] R NASLAIN, J Y ROSSGNOL, P HAGENMULLER et al. Synthesis and properties of new composite-materials for high-temperature applications based on carbon-fibers and C-SiC or C-TiC hybrid matrices. Revue De ChimieMinerale, 18, 544-564(1981).
[28] J RUAN, J S YANG, S M DONG et al. Interfacial optimization of SiC nanocomposites reinforced by SiC nanowires with high volume fraction. Journal of the American Ceramic Society, 102, 5033-5037(2019).
[29] Y ZHU, Y ZHANG, L S YAN. Interface between multi-layered CVD SiC coating and its graphite substrate. Equipment Environmetal Engineering, 16, 59-63(2019).
[30] J CHIN, P K GANTZEL, R G HUDSON. The structure of chemical vapor deposition sillicon carbide. Thin Solid Films, 40, 57-72(1977).
[31] M M MASLOV, L A OPENOV, A I PODILIVAEV. On the vineyard formula for the pre-exponential factor in the Arrhenius law.. Physics of the Solid State, 56, 1239-1244(2014).
[32] T N TIEGS. Fission product Pd-SiC interaction in irradiated coated-particle fuels. Nuclear Technology, 57, 389-398(2017).
[33] A I KINGON, L J LUTZ, P LIAW et al. Thermodynamic calculations for the chemical vapor deposition of silicon carbide. Journal of the American Ceramic Society, 66, 558-566(1983).
[34] M KAZUO, F KOUSAKU. Structure of chemically vapour deposited silicon carbide for coated fuel particles. Journal of Materials Science, 23, 699-706(1998).
[35] J C BYUNG, W P DONG, R K DAI. Chemical vapour deposition of silicon carbide by pyrolysis of methylchlorosilanes. Journal of Materials Science Letters, 16, 33-36(1997).
[36] D Y HAN, H MEI, S S XIAO et al. Porous SiCnw/SiC ceramics with unidirectionally aligned channels produced by freeze-drying and chemical vapor infiltration. Journal of the European Ceramic Society, 37, 915-921(2017).
[37] E S KANG, Y W KIM, H NAM. Multiple thermal resistance induced extremely low thermal conductivity in porous SiC-SiO2 ceramics with hierarchical porosity. Journal of the European Ceramic Society, 41, 1171-1180(2021).
[38] S KULTAYEVA, Y W KIM, I H SONG. Effects of dopants on electrical, thermal, and mechanical properties of porous SiC ceramics. Journal of the European Ceramic Society, 41, 4006-4015(2021).
[39] A DEY, N KAYAL, O CHAKRABARTI et al. Studies on processing of layered oxide-bonded porous SiC ceramic filter materials. International Journal of Applied Ceramic Technology, 18, 869-879(2021).
[40] Y S QI, K JIANG, C L ZHOU et al. Preparation and properties of high-porosity ZrB2-SiC ceramics by water-based freeze casting. Journal of the European Ceramic Society, 41, 2239-2246(2021).
[41] S RAJPOOT, J H HA, W KIMY. Effects of initial particle size on mechanical, thermal, and electrical properties of porous SiC ceramics. Ceramics International, 47, 8668-8676(2021).