[1] Krenkel W, Carbon fiber reinforced CMC for high-performance structures, Int. J. Appl. Ceram. Technol. 2004, 1: 188-200.
[2] Chen L Q, Yin X W, Fan X M, Chen M, Ma X K, Cheng L F, Zhang L T, Mechanical and electromagnetic shielding properties of carbon fiber reinforced silicon carbide matrix composites, Carbon 2015, 95: 10-19.
[3] Xu Y D, Cheng L F, Zhang L T, Yin H F, Yin X W, Mechanical properties of 3D fiber reinforced C/SiC composites, Mater. Sci. Eng. A-Struct. Mater. Prop. Microstruct. Process. 2001, 300: 196-202.
[4] Krenkel W, Berndt F, C/C-SiC composites for space applications and advanced friction systems, Mater. Sci. Eng. A-Struct. Mater. Prop. Microstruct. Process. 2005, 412: 177-181.
[5] Zhang R, Li W, Liu Y, Wang C, Wang J, Yang X, Cheng L, Machining parameter optimization of C/SiC composites using high power picosecond laser, Appl. Surf. Sci. 2015, 330: 321-331.
[6] Lamouroux F, Bertrand S, Pailler R, Naslain R, Cataldi M, Oxidation-resistant carbon-fiber-reinforced ceramic-matrix composites, Compos. Sci. Technol 1999, 59: 1073-1085.
[7] Li J X, Liu Y S, Nan B Y, Zhao Z F, Feng W, Zhang Q, Cheng L F, Microstructure and Properties of C/SiC-Diamond Composites Prepared by the Combination of CVI and RMI, Adv. Eng. Mater. 2019, 21: 11.
[8] Zhu Y Z, Huang Z R, Dong S M, Yuan M, Jiang D L, Manufacturing 2D carbon-fiber-reinforced SiC matrix composites by slurry infiltration and PIP process, Ceram. Int 2008, 34: 1201-1205.
[9] Xiang Y, Li W, Wang S, Chen Z H, Oxidation behavior of oxidation protective coatings for PIP-C/SiC composites at 1500 degrees C, Ceram. Int 2012, 38: 9-13.
[10] Wen J, Zhou S, Yi L, Sun B Z, Wang Y, Li G D, Xing Z F, Cao J, He H P, Xiang Y, Oxidation behavior and high-temperature flexural property of CVD-SiC-coated PIP-C/SiC composites, Ceram. Int 2018, 44: 16583-16588.
[11] Xu Y D, Cheng L F, Zhang L T, Carbon silicon carbide composites prepared by chemical vapor infiltration combined with silicon melt infiltration, Carbon 1999, 37: 1179-1187.
[12] Tang S F, Deng J Y, Du H F, Liu W C, Yang K, Fabrication and microstructure of C/SiC composites using a novel heaterless chemical vapor infiltration technique, J. Am. Ceram. Soc. 2005, 88: 3253-3255.
[13] Zou J Z, Zeng X R, Xiong X B, Microwave assisted chemical vapor infiltration to prepare carbon/carbon composites, New Carbon Mater. 2009, 24: 136-140.
[14] Gupta D, Evans J W, A mathematical-model for chemical vapor infiltration with microwave-heating and external cooling, J. Mater. Res. 1991, 6: 810-818.
[15] Vignoles G L, Duclous R, Gaillard S, Analytical stability study of the densification front in carbon- or ceramic-matrix composites processing by TG-CVI, Chem. Eng. Sci. 2007, 62: 6081-6089.
[16] Golecki I, Rapid vapor-phase densification of refractory composites, Mater. Sci. Eng. R-Rep. 1997, 20: 37-124.
[17] Bruneton E, Narcy B, Oberlin A, Carbon-carbon composites prepared by a rapid densification process I: Synthesis and physico-chemical data, Carbon 1997, 35: 1593-1598.
[18] Zhang F L, Machining Mechanism of Abrasive Water Jet on Ceramics, in: D.W. Zuo, H. Guo, G.X. Tang, W.D. Jin, C.J. Liu, C. Su (Eds.), Functional Manufacturing Technologies and Ceeusro I, Trans Tech Publications Ltd, Stafa-Zurich, 2010, pp. 212-215.
[19] Zou K R, Wang C, Zhang L Y, Experimental Study of Ultrasonic Vibration Drilling Ceramic Material, in: X.H. Liu, Z.H. Bai, Y.H. Shauang, C.L. Zhou, J. Shao (Eds.), Advanced Materials and Process Technology, Pts 1-3, Trans Tech Publications Ltd, Stafa-Zurich, 2012, pp. 1863-1868.
[20] Fiedler S, Irsig R, Tiggesbaumker J, Schuster C, Merschjann C, Rothe N, Lochbrunner S, Vehse M, Seitz H, Klinkenberg E D, Meiwes-Broer K H, Machining of biocompatible ceramics with femtosecond laser pulses, Biomed. Eng.-Biomed. Tech. 2013, 58: 2.
[21] Burck P, Wiegel K, Laser machining of Si3N4 ceramics, Opt. Quantum Electron. 1995, 27: 1349-1358.
[22] Pachaury Y, Tandon P, An overview of electric discharge machining of ceramics and ceramic based composites, J. Manuf. Process. 2017, 25: 369-390.
[23] Liu Y, Wang C, Li W, Zhang L, Yang X, Cheng G, Zhang Q, Effect of energy density and feeding speed on micro-hole drilling in C/SiC composites by picosecond laser, J. Mater. Process. Technol. 2014, 214: 3131-3140.
[24] Chichkov B N, Momma C, Nolte S, vonAlvensleben F, Tunnermann A, Femtosecond, picosecond and nanosecond laser ablation of solids, Appl. Phys. A-Mater. Sci. Process. 1996, 63: 109-115.
[25] Liu X, Du D, Mourou G, Laser ablation and micromachining with ultrashort laser pulses, IEEE J. Quantum Electron. 1997, 33: 1706-1716.
[26] Wang J, Cheng L F, Liu Y S, Zhang L T, Liu X Y, Zhang Y, Zhang Q, Enhanced densification and mechanical properties of carbon fiber reinforced silicon carbide matrix composites via laser machining aided chemical vapor infiltration, Ceram. Int 2017, 43: 11538-11541.
[27] Wang J, Zhang Y, Liu Y, Cao L, Chen J, Effects of initial density during laser machining assisted CVI process and its influence on strength of C/SiC composites, Ceram. Int 2020, 46: 11743-11746.
[28] Wang J, Chen X, Guan K, Cheng L F, Zhang L T, Liu Y S, Effects of channel modification on microstructure and mechanical properties of C/SiC composites prepared by LA-CVI process, Ceram. Int 2018, 44: 16414-16420.
[29] Shemyakin E I, Kurlenya M V, Oparin V N, Reva V N, Glushikhin F P, Rozenbaum M A, Tropp E A, Zonal disintegration of rocks around underground workings.4. practical applications, Soviet Mining Science Ussr 1989, 25: 297-302.
[30] Wang J, Cao L, Liu Y, Zhang Y, Fang H, Chen J, Fabrication of improved flexural strength C/SiC composites via LA-CVI method using optimized spacing of mass transfer channels, J. Eur. Ceram. Soc. 2020, 40: 2828-2833.
[31] Cao L, Liu Y, Zhang Y, Wang J, Chen J, Enhancing thermal conductivity of C/SiC composites containing heat transfer channels, J. Eur. Ceram. Soc. 2020, 40: 3520-3527.
[32] Wu M L, Ren C Z, Xu H Z, Comparative study of micro topography on laser ablated C/SiC surfaces with typical uni-directional fibre ending orientations, Ceram. Int 2016, 42: 7929-7942.