[2] Z YANG, F LI, G CHAI. Status and perspective of China’s nuclear safety philosophy and requirements in the post-fukushima era. Frontiers in Energy Research, 819634(2022).
[6] H V PHAM, M KURATA, M STEINBRUECK. Steam oxidation of silicon carbide at high temperatures for the application as accident tolerant fuel cladding, an overview. Thermo, 151-167(2021).
[7] C P DECK, G M JACOBSEN, J SHEEDER et al. Characterization of SiC-SiC composites for accident tolerant fuel cladding. Journal of Nuclear Materials, 667-681(2015).
[8] Y KATOH, L L SNEAD. Silicon carbide and its composites for nuclear applications-historical overview. Journal of Nuclear Materials, 151849(2019).
[9] K TAKAAKI, K YUTAI, N TAKASHI. Design and strategy for next- generation silicon carbide composites for nuclear energy. Journal of Nuclear Materials, 152375(2020).
[10] J STEIBEL. Ceramic matrix composites taking flight at GE Aviation. Am. Ceram. Soc. Bull, 32-36(2019).
[12] M I IDRIS, H KONISHI, M IMAI et al. Neutron irradiation swelling of SiC and SiCf/SiC for advanced nuclear applications, 328-336(2015).
[13] K A TERRANI. Accident tolerant fuel cladding development: promise, status, and challenges. Journal of Nuclear Materials, 13-30(2018).
[14] A HASEGAWA, G E YOUNGBLOOD, R H JONES. Effect of irradiation on the microstructure of Nicalon fibers. Journal of Nuclear Materials, 245-248(1996).
[15] M C OSBORNE, C R HUBBARD, L L SNEAD et al. Neutron irradiation effects on the density, tensile properties and microstructural changes in Hi-Nicalon (TM) and Sylramic (TM) SiC fibers. Journal of Nuclear Materials, 67-77(1998).
[16] C H HENAGER, G E YOUNGBLOOD, D J SENOR et al. Dimensional stability and tensile strength of irradiated Nicalon-CG and Hi-Nicalon fibers. Journal of Nuclear Materials, 60-66(1998).
[17] T HINOKI, Y KATOH, A KOHYAMA. Effect of fiber properties on neutron irradiated SiC/SiC composites. Materials Transactions, 617-621(2002).
[18] G E YOUNGBLOOD, R H JONES, A KOHYAMA et al. Radiation response of SiC-based fibers. Journal of Nuclear Materials, 1551-1556(1998).
[19] T KOYANAGI, Y KATOH. Mechanical properties of SiC composites neutron irradiated under light water reactor relevant temperature and dose conditions. Journal of Nuclear Materials, 46-54(2017).
[20] G NEWSOME, L L SNEAD, T HINOKI et al. Evaluation of neutron irradiated silicon carbide and silicon carbide composites. Journal of Nuclear Materials, 76-89(2007).
[21] http://ngs-advanced-fibers.com/eng/item/index.html
[22] https://www.ube.com/contents/en/chemical/continuous_inorganic_fiber/tyranno_fiber.html
[23] H ICHIKAWA. Polymer-derived ceramic fibers. Annual Review of Materials Research, 335-356(2016).
[24] Y KATOH, L L SNEAD, T NOZAWA et al. Thermophysical and mechanical properties of near-stoichiometric fiber CVI SiC/SiC composites after neutron irradiation at elevated temperatures. Journal of Nuclear Materials, 48-61(2010).
[25] J BRAUN, C SAUDER. Mechanical behavior of SiC/SiC composites reinforced with new Tyranno SA4 fibers: effect of interphase thickness and comparison with Tyranno SA3 and Hi- Nicalon S reinforced composites. Journal of Nuclear Materials, 153367(2022).
[26] P R WANG, Y Z GOU, H WANG. Third generation SiC fibers for nuclear applications. Journal of Inorganic Materials, 525-531(2020).
[27] Y KATOH, K OZAWA, C SHIH et al. Continuous SiC fiber, CVI SiC matrix composites for nuclear applications: properties and irradiation effects. Journal of Nuclear Materials, 448-476(2014).
[28] B N NGUYEN, C H HENAGER. Fiber/matrix interfacial thermal conductance effect on the thermal conductivity of SiC/SiC composites. Journal of Nuclear Materials, 11-20(2013).
[29] S JACQUES, A LOPEZ-MARURE, C VINCENT et al. SiC/SiC minicomposites with structure-graded BN interphases. Journal of the European Ceramic Society, 1929-1938(2000).
[30] X Y CAO, X W YIN, X M FAN et al. Effect of PyC interphase thickness on mechanical behaviors of SiBC matrix modified C/SiC composites fabricated by reactive melt infiltration. Carbon, 886-895(2014).
[31] R R NASLAIN, R J F PAILLER, J L LAMON. Single and multilayered interphases in SiC/SiC composites exposed to severe environmental conditions: an overview. International Journal of Applied Ceramic Technology, 263-275(2010).
[32] L L SNEAD, T D BURCHELL, Y KATOH. Swelling of nuclear graphite and high quality carbon fiber composite under very high irradiation temperature. Journal of Nuclear Materials, 55-61(2008).
[33] Y KATOH, T NOZAWA, C H SHIH. High-dose neutron irradiation of Hi-Nicalon Type S silicon carbide composites. Part 2: Mechanical and physical properties. Journal of Nuclear Materials, 450-457(2015).
[34] T NOZAWA, Y KATOH, L L SNEAD. The effects of neutron irradiation on shear properties of monolayered PyC and multilayered PyC/SiC interfaces of SiC/SiC composites. Journal of Nuclear Materials, 685-691(2007).
[35] T KOYANAGI, T NOZAWA, Y KATOH et al. Mechanical property degradation of high crystalline SiC fiber-reinforced SiC matrix composite neutron irradiated to -100 displacements per atom. Journal of the European Ceramic Society, 1087-1094(2018).
[37] L L SNEAD, E LARA-CURZIO. Interphase integrity of neutron irradiated SiC composites. MRS Online Proceedings Library, 273-278(1998).
[38] T KOYANAGI, Y KATOH, T NOZAWAET AL. Recent progress in the development of SiC composites for nuclear fusion applications. Journal of Nuclear Materials, 544-555(2018).
[39] S LAMON J POMPIDOU. Analysis of crack deviation in ceramic matrix composites and multilayers based on the cook and gordon mechanism. Composites Science and Technology, 2052-2060(2007).
[40] H LI, G N MORSCHER, J LEE et al. Tensile and stress-rupture behavior of SiC/SiC minicomposite containing chemically vapor deposited zirconia interphase. Journal of the American Ceramic Society, 1726-1733(2004).
[41] A V UTKIN, A A MATVIENKO, A T TITOV et al. Multiple zirconia interphase for SiC/SiCf composites. Surface and Coatings Technology(2011).
[42] V PROKIP, V LOZANOV, N MOROZOVA et al. The zirconia- based interfacial coatings on SiC fibers obtained by different chemical methods. Materials Today: Proceedings, 1861-1864(2019).
[43] R L CALLENDER, A R BARRON. Novel route to alumina and aluminate interlayer coatings for SiC, carbon, and Kevlart® fiber- reinforced ceramic matrix composites using carboxylate-alumoxane nanoparticles. Journal of Materials Research, 2228-2237(2011).
[44] N IGAWA, T TAGUCHI, R YAMADA et al. Preparation of silicon-based oxide layer on high-crystalline SiC fiber as an interphase in SiC/SiC composites. Journal of Nuclear Materials, 554-557(2004).
[45] Y SHI, F LUO, D DING et al. Effects of ZrO2 interphase on mechanical and microwave absorbing properties of SiCf/SiC composites. Physica Status Solidi (A), 2668-2673(2013).
[46] M RUGGLES-WRENN, N BOUCHER, C PRZYBYLA. Fatigue of three advanced SiC/SiC ceramic matrix composites at 1200 ℃ in air and in steam. International Journal of Applied Ceramic Technology, 3-15(2018).
[47] S JACQUES, I JOUANNY, O LEDAIN et al. Nanoscale multilayered and porous carbide interphases prepared by pressure- pulsed reactive chemical vapor deposition for ceramic matrix composites. Applied Surface Science, 102-109(2013).
[48] C ANG, S ZINKLE, C SHIH et al. Phase stability, swelling, microstructure and strength of Ti3SiC2-TiC ceramics after low dose neutron irradiation. Journal of Nuclear Materials, 44-53(2017).
[49] C ANG, C SILVA, C SHIH et al. Anisotropic swelling and microcracking of neutron irradiated Ti3AlC2-Ti5Al2C3 materials. Scripta Materialia, 74-78(2016).
[50] D J TALLMAN, E N HOFFMAN, E N CASPI et al. Effect of neutron irradiation on select MAX phases. Acta Materialia, 132-143(2015).
[51] I FILBERT-DEMUT, G P BEI, T HOSCHEN et al. Influence of Ti3SiC2 fiber coating on interface and matrix cracking in an SiC fiber-reinforced polymer-derived ceramic. Advanced Engineering Materials, 1142-1148(2015).
[52] M LI, X B ZHOU, H YANG et al. The critical issues of SiC materials for future nuclear systems. Scripta Materialia, 149-153(2018).
[53] M LI, K WANG, J WANG et al. Preparation of TiC/Ti2AlC coating on carbon fiber and investigation of the oxidation resistance properties. Journal of the American Ceramic Society, 5269-5280(2018).
[54] K WANG, M LI, Y Q LIANG et al. Interface modification of carbon fibers with TiC/Ti2AlC coating and its effect on the tensile strength. Ceramics International, 4661-4666(2019).
[55] J WANG, K WANG, X L PEI et al. Irradiation behavior of Cf/SiC composite with titanium carbide (TiC)-based interphase. Journal of Nuclear Materials, 10-15(2019).
[56] H ZHONG, Z WANG, H ZHOU et al. Properties and microstructure evolution of Cf/SiC composites fabricated by polymer impregnation and pyrolysis (PIP) with liquid polycarbosilane. Ceramics International, 7387-7392(2017).
[57] X LI, X PEI, X ZHONG et al. Highly effective free-radical-catalyzed curing of hyperbranched polycarbosilane for near stoichiometric SiC ceramics. Journal of the American Ceramic Society, 1041-1048(2019).
[58] A RAHMAN, S C ZUNJARRAO, R P SINGH. Effect of degree of crystallinity on elastic properties of silicon carbide fabricated using polymer pyrolysis. Journal of the European Ceramic Society, 3285-3292(2016).
[59] Y KATOH, M KOTANI, H KISHIMOTO et al. Properties and radiation effects in high-temperature pyrolyzed PIP-SiC/SiC. Journal of Nuclear Materials(2001).
[60] Z LUO, X ZHOU, J YU et al. High-performance 3D SiC/PyC/SiC composites fabricated by an optimized PIP process with a new precursor and a thermal molding method. Ceramics International, 6525-6532(2014).
[61] J YIN, S H LEE, L FENG et al. Fabrication of SiCf/SiC composites by hybrid techniques of electrophoretic deposition and polymer impregnation and pyrolysis. Ceramics International, 16431-16435(2016).
[62] M LI, D YANG, H WANG et al. Fabrication of a 3D4d braided SiCf/SiC composite via PIP process assisted with an EPD method. Ceramics International, 11668-11676(2019).
[63] A IVEKOVIĆ, G DRAŽIĆ, S NOVAK. Densification of a SiC- matrix by electrophoretic deposition and polymer infiltration and pyrolysis process. Journal of the European Ceramic Society, 833-840(2011).
[64] W J KIM, S M KANG, J Y PARK et al. Effect of a SiC whisker formation on the densification of Tyranno SA/SiC composites fabricated by the CVI process. Fusion Engineering and Design, 931-936(2006).
[65] S M KANG, J Y PARK, W J KIM et al. Densification of SiCf/SiC composite by the multi-step of whisker growing and matrix filling. Journal of Nuclear Materials, 530-533(2004).
[66] P TAO, Y WANG. Fabrication of highly dense three-layer SiC cladding tube by chemical vapor infiltration method. Journal of the American Ceramic Society, 6939-6945(2019).
[67] A KOHYAMA, Y KATOH. Advanced SiC/SiC ceramic composites: developments and applications in energy systems. Ceramic Transactions, 3-18(2002).
[69] A KOHYAMA, S DONG, Y KATOH. Development of SiC/SiC composites by Nano-Infiltration and Transient Eutectoid (NITE) process. Ceramic Engineering and Science Proceedings, 8(2002).
[70] H KONISHI, M I IDRIS, M IMAI et al. Neutron irradiation effects of oxide sintering additives for SiCf/SiC composites. Energy Procedia, 306-312(2015).
[71] C M PARISH, K A TERRANI, Y J KIM et al. Microstructure and hydrothermal corrosion behavior of NITE-SiC with various sintering additives in LWR coolant environments. Journal of the European Ceramic Society, 1261-1279(2017).
[72] H W YU, P FITRIANI, S LEE et al. Fabrication of the tube- shaped SiCf/SiC by hot pressing. Ceramics International, 7890-7896(2015).
[73] J C MARGIOTTA, D ZHANG, D C NAGLE. Microstructural evolution during silicon carbide (SiC) formation by liquid silicon infiltration using optical microscopy. International Journal of Refractory Metals and Hard Materials, 191-197(2010).
[76] J A DICARLO, H M YUN, MORSCHER, N G et al. SiC/SiC composites for 1200 ℃ and above. https://doi.org/10.1007/0-387-23986-3_4
[77] G JE. CMC Research at NASA Glenn in 2019: Recent Progress and Plans. NASA: Ceramic & Polymer Composites Branch(2019).
[78] R LIU, F WANG, J ZHANG et al. Effects of CVI SiC amount and deposition rates on properties of SiCf/SiC composites fabricated by hybrid chemical vapor infiltration (CVI) and precursor infiltration and pyrolysis (PIP) routes. Ceramics International, 26971-26977(2021).
[81] L WANG, Z WANG, S DONG et al. Finite element simulation of stress distribution and development of Cf/SiC ceramic-matrix composite coated with single layer SiC coating during thermal shock. Composites Part B: Engineering, 204-214(2013).
[82] L LI, Y SONG, Y C SUN. Modeling the tensile behavior of unidirectional C/SiC ceramic-matrix composites. Mechanics of Composite Materials, 659-672(2014).
[83] P MEYER, A WAAS. FEM predictions of damage in continous fiber ceramic matrix composites under transverse tension using the crack band method. Acta Materialia, 292-303(2016).
[84] J WANG, Y CHEN, Y FENG et al. Influence of porosity on anisotropic thermal conductivity of SiC fiber reinforced SiC matrix composite: a microscopic modeling study. Ceramics International, 28693-28700(2020).
[85] S K MITAL, B A BEDNARCYK, S M ARNOLD et al. Modeling of melt-infiltrated SiC/SiC composite properties(2009).
[86] D A VAJARI, C GONZALEZ, J LLORCA et al. A numerical study of the influence of microvoids in the transverse mechanical response of unidirectional composites. Composites Science and Technology, 46-54(2014).
[87] D A VAJARI. A micromechanical study of porous composites under longitudinal shear and transverse normal loading. Composite Structures, 266-276(2015).
[88] Y FENG, J WANG, N SHANG et al. Multiscale modeling of SiCf/SiC nuclear fuel cladding based on FE-simulation of braiding process. Frontiers in Materials, 634112(2021).
[89] J TANG, G ZHAO, J WANG et al. Computational geometry- based 3D yarn path modeling of wound SiCf/SiC-cladding tubes and its application to meso-scale finite element model. Frontiers in Materials, 701205(2021).
[90] B R BICKMORE, J C WHEELER, B BATES et al. Reaction pathways for quartz dissolution determined by statistical and graphical analysis of macroscopic experimental data. Geochimica Et Cosmochimica Acta, 4521-4536(2008).
[91] P M DOVE, N Z HAN, J J DE YOREO. Mechanisms of classical crystal growth theory explain quartz and silicate dissolution behavior. Proceedings of the National Academy of Sciences of the United States of America, 15357-15362(2005).
[92] T V GERYA, W V MARESCH, M BURCHARD et al. Thermodynamic modeling of solubility and speciation of silica in H2O-SiO2 fluid up to 1300 ℃ and 20 kbar based on the chain reaction formalism. European Journal of Mineralogy, 269-283(2005).
[93] V A HACKLEY, U PAIK, B H KIM et al. Aqueous processing of sintered reaction-bonded silicon nitride.1. Dispersion properties of silicon powder. Journal of the American Ceramic Society, 1781-1788(1997).
[94] H HIRAYAMA, T KAWAKUBO, A GOTO et al. Corrosion behavior of silicon carbide in 290 ℃ water. Journal of the American Ceramic Society, 2049-2053(1989).
[95] N S JACOBSON, Y G GOTOTSI, M YOSHIMURA. Thermodynamic and experimental study of carbon formation on carbides under hydrothermal conditions. Journal of Materials Chemistry, 595-601(1995).
[96] K A TERRANI, Y YANG, Y J KIM et al. Hydrothermal corrosion of SiC in LWR coolant environments in the absence of irradiation. Journal of Nuclear Materials, 488-498(2015).
[97] D KIM, H J LEE, C JANG et al. Influence of microstructure on hydrothermal corrosion of chemically vapor processed SiC composite tubes. Journal of Nuclear Materials, 6-13(2017).
[98] W J KIM, H S HWANG, J Y PARK. Corrosion behavior of reaction-bonded silicon carbide ceramics in high-temperature water. Journal of Materials Science Letters, 733-735(2002).
[99] W J KIM, H S HWANG, J Y PARK et al. Corrosion behaviors of sintered and chemically vapor deposited silicon carbide ceramics in water at 360 ℃. Journal of Materials Science Letters, 581-584(2003).
[100] D KIM, H G LEE, Y PARK et al. Effect of dissolved hydrogen on the corrosion behavior of chemically vapor deposited SiC in a simulated pressurized water reactor environment. Corrosion Science, 304-309(2015).
[101] L TAN, T R ALLEN, E BARRINGER. Effect of microstructure on the corrosion of CVD-SiC exposed to supercritical water. Journal of Nuclear Materials, 95-101(2009).
[102] J H SHIN, D KIM, H G LEE et al. Factors affecting the hydrothermal corrosion behavior of chemically vapor deposited silicon carbides. Journal of Nuclear Materials, 350-356(2019).
[103] L HALLSTADIUS, S JOHNSON, E LAHODA. Cladding for high performance fuel. Progress in Nuclear Energy, 71-76(2012).
[104] D KIM, H G LEE, J Y PARK et al. Fabrication and measurement of hoop strength of SiC triplex tube for nuclear fuel cladding applications. Journal of Nuclear Materials, 29-36(2015).
[105] Y M QIN, X Q LI, C X LIU et al. Effect of deposition temperature on the corrosion behavior of CVD SiC coatings on SiCf/SiC composites under simulated PWR conditions. Corrosion Science, 13(2021).
[106] H YANG, X Q LI, C X LIU et al. Hydrothermal corrosion behavior of SiCf/SiC composites candidate for PWR accident tolerant fuel cladding. Ceramics International, 22865-22873(2018).
[107] J Y PARK, I H KIM, Y I JUNG et al. Long-term corrosion behavior of CVD SiC in 360 ℃ water and 400 ℃ steam. Journal of Nuclear Materials, 603-607(2013).
[108] P J DOYLE, T KOYANAGI, C ANG et al. Evaluation of the effects of neutron irradiation on first-generation corrosion mitigation coatings on SiC for accident-tolerant fuel cladding. Journal of Nuclear Materials, 152203(2020).
[109] J Q XI, C LIU, D MORGAN et al. An unexpected role of H during SiC corrosion in water. Journal of Physical Chemistry C, 9394-9400(2020).
[110] S KONDO, M LEE, T HINOKI et al. Effect of irradiation damage on hydrothermal corrosion of SiC. Journal of Nuclear Materials, 36-42(2015).
[111] S KONDO, S MOURI, Y HYODO et al. Role of irradiation- induced defects on SiC dissolution in hot water. Corrosion Science, 402-407(2016).
[112] G L LIU, Y P LI, Z B HE et al. Investigation of microstructure and nanoindentation hardness of C+ & He+ irradiated nanocrystal sic coatings during annealing and corrosion. Materials (Basel), 5567(2020).
[113] L L SNEAD, T NOZAWA, Y KATOH et al. Handbook of SiC properties for fuel performance modeling. Journal of Nuclear Materials, 377(2007).
[114] Y R LIN, L G CHEN, C Y HSIEH et al. Atomic configuration of point defect clusters in ion-irradiated silicon carbide. Scientific Reports, 14635(2017).
[115] Y MAEDA, K FUKAMI, S KONDO et al. Irradiation-induced point defects enhance the electrochemical activity of 3C-SiC: an origin of SiC corrosion. Electrochemistry Communications, 15-18(2018).
[116] P A MOUCHE, C ANG, T KOYANAGI et al. Characterization of PVD Cr, CrN, and TiN coatings on SiC. Journal of Nuclear Materials, 151781(2019).
[117] S S RAIMAN, C ANG, P DOYLE et al. Hydrothermal corrosion of SiC materials for accident tolerant fuel cladding with and without mitigation coatings, 259-267(2017).
[118] M WAGIH, B SPENCER, J HALES et al. Fuel performance of chromium-coated zirconium alloy and silicon carbide accident tolerant fuel claddings. Annals of Nuclear Energy, 304-318(2018).
[119] R ISHIBASHI, K ISHIDA, T KONDO et al. Corrosion-resistant metallic coating on silicon carbide for use in high-temperature water. Journal of Nuclear Materials, 153214(2021).
[120] P J DOYLE, C ANG, L SNEAD et al. Hydrothermal corrosion of first-generation dual-purpose coatings on silicon carbide for accident- tolerant fuel cladding. Journal of Nuclear Materials, 152695(2021).
[121] Z HE, C LI, X SI et al. Wetting of Si-14Ti alloy on SiCf/SiC and C/C composites and their brazed joint at high temperatures. Ceramics International, 13845-13852(2021).
[122] Z HE, L SUN, C LI et al. Wetting and brazing of Cf/C composites with Si-Zr eutectic alloys: the formation of nano- and coarse-SiC reaction layers. Carbon, 92-103(2020).
[123] Z LUO, D JIANG, J ZHANG et al. Development of SiC-SiC joint by reaction bonding method using SiC/C tapes as the interlayer. Journal of the European Ceramic Society, 3819-3824(2012).
[124] J DENG, B LU, K HU et al. Thermodynamics equilibrium analysis on the chemical vapor deposition of HfC as coatings for ceramic matrix composites with HfClx(x=2-4)-CyHz(CH4, C2H4 and C3H6)-H2-Ar system. Advanced Composites and Hybrid Materials, 102-114(2018).
[125] J LI, L LIU, Y WU et al. A high temperature Ti-Si eutectic braze for joining SiC. Materials Letters, 3135-3138(2008).
[126] H DONG, S LI, Y TENG et al. Joining of SiC ceramic-based materials with ternary carbide Ti3SiC2. Materials Science and Engineering: B, 60-64(2011).
[127] H DONG, Y YU, X JIN et al. Microstructure and mechanical properties of SiC-SiC joints joined by spark plasma sintering. Ceramics International, 14463-14468(2016).
[128] M SINGH, T MATSUNAGA, H T LIN et al. Microstructure and mechanical properties of joints in sintered SiC fiber-bonded ceramics brazed with Ag-Cu-Ti alloy. Materials Science and Engineering: A, 69-76(2012).
[129] S GRASSO, P TATARKO, S RIZZO et al. Joining of β-SiC by spark plasma sintering. Journal of the European Ceramic Society, 1681-1686(2014).
[130] S RIZZO, S GRASSO, M SALVO et al. Joining of C/SiC composites by spark plasma sintering technique. Journal of the European Ceramic Society, 903-913(2014).
[131] M FERRARIS, M SALVO, V CASALEGNO et al. Joining of SiC-based materials for nuclear energy applications. Journal of Nuclear Materials, 379-382(2011).
[132] M FERRARIS, V CASALEGNO, S RIZZO et al. Effects of neutron irradiation on glass ceramics as pressure-less joining materials for SiC based components for nuclear applications. Journal of Nuclear Materials, 166-172(2012).
[133] M SINGH. Joining of sintered silicon carbide ceramics for high- temperature applications. Journal of Materials Science Letters, 459-461(1998).
[134] M SINGH. A reaction forming method for joining of silicon carbide-based ceramics. Scripta Materialia, 1151-1154(1997).
[135] C A LEWINSOHN, R H JONES, P COLOMBO et al. Silicon carbide-based materials for joining silicon carbide composites for fusion energy applications. Journal of Nuclear Materials, 1232-1236(2002).
[136] D H JEONG, A SEPTIADI, P FITRIANI et al. Joining of SiCf/ SiC using polycarbosilane and polysilazane preceramic mixtures. Ceramics International, 10443-10450(2018).
[137] Y KATOH, L L SNEAD, T CHENG et al. Radiation-tolerant joining technologies for silicon carbide ceramics and composites. Journal of Nuclear Materials, 497-511(2014).
[138] H C JUNG, Y H PARK, J S PARK et al. R&D of joining technology for SiC components with channel. Journal of Nuclear Materials, 847-851(2009).
[139] P COLOMBO, B RICCARDI, A DONATO et al. Joining of SiC/SiCf ceramic matrix composites for fusion reactor blanket applications. Journal of Nuclear Materials, 127-135(2000).
[140] M FERRARIS, M SALVO, V CASALEGNO et al. Joining of machined SiC/SiC composites for thermonuclear fusion reactors. Journal of Nuclear Materials, 410-415(2008).
[141] S FAN, J LIU, X MA et al. Microstructure and properties of SiCf/SiC joint brazed by Y-Al-Si-O glass. Ceramics International, 8656-8663(2018).
[142] L WANG, S FAN, H SUN et al. Pressure-less joining of SiCf/SiC composites by Y2O3-Al2O3-SiO2 glass: microstructure and properties. Ceramics International, 27046-27056(2020).
[143] L WANG, S FAN, S YANG et al. Microstructure and properties of SiCf/SiC composite joints with CaO-Y2O3-Al2O3-SiO2 interlayer. Ceramics International, 16603-16613(2021).
[144] P TATARKO, V CASALEGNO, C HU et al. Joining of CVD-SiC coated and uncoated fibre reinforced ceramic matrix composites with pre-sintered Ti3SiC2 MAX phase using spark plasma sintering. Journal of the European Ceramic Society, 3957-3967(2016).
[145] P TATARKO, Z CHLUP, A MAHAJAN et al. High temperature properties of the monolithic CVD β-SiC materials joined with a pre-sintered MAX phase Ti3SiC2 interlayer via solid-state diffusion bonding. Journal of the European Ceramic Society, 1205-1216(2017).
[146] P FITRIANI, A SEPTIADI, J D HYUK et al. Joining of SiC monoliths using a thin MAX phase tape and the elimination of joining layer by solid-state diffusion. Journal of the European Ceramic Society, 3433-3440(2018).
[147] X ZHOU, H YANG, F CHEN et al. Joining of carbon fiber reinforced carbon composites with Ti3SiC2 tape film by electric field assisted sintering technique. Carbon, 106-115(2016).
[148] X ZHOU, Y H HAN, X SHEN et al. Fast joining SiC ceramics with Ti3SiC2 tape film by electric field-assisted sintering technology. Journal of Nuclear Materials, 322-327(2015).
[149] X ZHOU, Y LI, Y LI et al. Residual thermal stress of SiC/Ti3SiC2/ SiC joints calculation and relaxed by post-annealing. International Journal of Applied Ceramic Technology, 1157-1165(2018).
[150] X ZHOU, Z LIU, Y LI et al. SiC ceramics joined with an in-situ reaction gradient layer of TiC/Ti3SiC2 and interface stress distribution simulations. Ceramics International, 15785-15794(2018).
[151] A SEPTIADI, P FITRIANI, A S SHARMA et al. Low pressure joining of SiCf/SiC composites using Ti3AlC2 or Ti3SiC2 MAX phase tape. Journal of the Korean Ceramic Society, 340-348(2017).
[152] P FITRIANI, H KWON, X ZHOU et al. Joining of SiCf/SiC using a layered Ti3SiC2-SiCw and TiC gradient filler. Journal of the European Ceramic Society, 1043-1051(2020).
[153] P FITRIANI, D H YOON. Joining of SiCf/SiC using a Ti3AlC2 filler and subsequent elimination of the joining layer. Ceramics International, 22943-22949(2018).
[154] H YANG, X ZHOU, W SHI et al. Thickness-dependent phase evolution and bonding strength of SiC ceramics joints with active Ti interlayer. Journal of the European Ceramic Society, 1233-1241(2017).
[155] X ZHOU, J LIU, S ZOU et al. Almost seamless joining of SiC using an in-situ reaction transition phase of Y3Si2C2. Journal of the European Ceramic Society, 259-266(2020).
[156] P WAN, M LI, K XU et al. Seamless joining of silicon carbide ceramics through an sacrificial interlayer of Dy3Si2C2. Journal of the European Ceramic Society, 5457-5462(2019).
[157] L K SHI, X ZHOU, K XU et al. Low temperature seamless joining of SiC using a ytterbium film. Journal of the European Ceramic Society, 7507-7515(2021).
[158] Z ZHANG, X DUAN, D JIA et al. On the formation mechanisms and properties of MAX phases: a review. Journal of the European Ceramic Society, 3851-3878(2021).
[159] X ZHOU, L JING, Y D KWON et al. Fabrication of SiCw/Ti3SiC2 composites with improved thermal conductivity and mechanical properties using spark plasma sintering. Journal of Advanced Ceramics, 462-470(2020).
[160] H B ZHANG, C F HU, K SATO et al. Tailoring Ti3AlC2 ceramic with high anisotropic physical and mechanical properties. Journal of the European Ceramic Society, 393-397(2015).
[161] Y BAI, X HE, C ZHU et al. Microstructures, electrical, thermal, and mechanical properties of bulk Ti2AlC synthesized by self- propagating high-temperature combustion synthesis with Pseudo Hot Isostatic Pressing. Journal of the American Ceramic Society, 358-364(2012).
[162] C HU, Y SAKKA, T NISHIMURA et al. Physical and mechanical properties of highly textured polycrystalline Nb4AlC3 ceramic. Sci. Technol. Adv. Mater, 044603(2011).
[163] M W BARSOUM. The MN+1AXN phases: a new class of solids: thermodynamically stable nanolaminates. Progress in Solid State Chemistry, 201-281(2000).
[164] Z M SUN. Progress in research and development on MAX phases: a family of layered ternary compounds. International Materials Reviews, 143-166(2011).
[165] T EL-RAGHY, A ZAVALIANGOS, M W BARSOUM et al. Damage mechanisms around hardness indentations in Ti3SiC2. Journal of the American Ceramic Society, 513-516(1997).
[166] D J TALLMAN, L HE, B L GARCIA-DIAZ et al. Effect of neutron irradiation on defect evolution in Ti3SiC2 and Ti2AlC. Journal of Nuclear Materials, 194-206(2016).
[167] T YANG, C WANG, C A TAYLOR et al. The structural transitions of Ti3AlC2 induced by ion irradiation. Acta Materialia, 351-359(2014).
[168] C WANG, T YANG, S KONG et al. Effects of He irradiation on Ti3AlC2: damage evolution and behavior of He bubbles. Journal of Nuclear Materials, 606-611(2013).
[169] L L SNEAD, R SCHOLZ, A HASEGAWA et al. Experimental simulation of the effect of transmuted helium on the mechanical properties of silicon carbide. Journal of Nuclear Materials, 1141-1145(2002).
[170] J CHEN, P JUNG, H TRINKAUS. Evolution of Helium platelets and associated dislocation loops in α-SiC. Physical Review Letters, 2709-2712(1999).
[171] R B GREGORY, T A WETTEROTH, S R WILSON et al. Effects of irradiation temperature and dose on exfoliation of H+-implanted silicon carbide. Applied Physics Letters, 2623-2625(1999).
[172] K HOJOU, S FURUNO, K N KUSHITA et al. EELS analysis of SiC crystals under hydrogen and helium dual-ion beam irradiation. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms(1998).
[173] S MIWA, A HASEGAWA, T TAGUCHI et al. Cavity formation in a SiC/SiC composite under simultaneous irradiation of hydrogen, helium and silicon ions. Materials Transactions, 536-542(2005).
[174] A UDAYAKUMAR, GANESH A SRI, S RAJA et al. Effect of intermediate heat treatment on mechanical properties of SiCf/SiC composites with BN interphase prepared by ICVI. Journal of the European Ceramic Society, 1145-1153(2011).
[175] E BUET, C SAUDER, D SORNIN et al. Influence of surface fibre properties and textural organization of a pyrocarbon interphase on the interfacial shear stress of SiC/SiC minicomposites reinforced with Hi-Nicalon S and Tyranno SA3 fibres. Journal of the European Ceramic Society, 179-188(2014).
[176] F REBILLAT, J LAMON, R NASLAIN et al. Interfacial bond strength in SiC/C/SiC composite materials, as studied by single- fiber push-out tests. Journal of the American Ceramic Society, 965-978(1998).
[177] H YU, X ZHOU, W ZHANG et al. Mechanical behavior of SiCf/ SiC composites with alternating PyC/SiC multilayer interphases. Materials & Design, 320-324(2013).
[178] L W YANG, H T LIU, H F CHENG. Processing-temperature dependent micro- and macro-mechanical properties of SiC fiber reinforced SiC matrix composites. Composites Part B: Engineering, 152-161(2017).
[179] H T LIU, L W YANG, X SUN et al. Enhancing the fracture resistance of carbon fiber reinforced SiC matrix composites by interface modification through a simple fiber heat-treatment process. Carbon, 435-443(2016).
[180] L W YANG, H T LIU, R JIANG et al. Weak interface dominated high temperature fracture strength of carbon fiber reinforced mullite matrix composites. Journal of the European Ceramic Society, 2991-2996(2017).
[181] H T LIU, L W YANG, S HAN et al. Interface controlled micro- and macro-mechanical properties of aluminosilicate fiber reinforced SiC matrix composites. Journal of the European Ceramic Society, 883-890(2017).
[182] L W YANG, J Y WANG, H T LIU et al. Sol-Gel temperature dependent ductile-to-brittle transition of aluminosilicate fiber reinforced silica matrix composite. Composites Part B: Engineering, 79-89(2017).
[183] R JIANG, L YANG, H LIU et al. A multiscale methodology quantifying the sintering temperature-dependent mechanical properties of oxide matrix composites. Journal of the American Ceramic Society, 3168-3180(2018).