[3] S XU, C ZHENG, Y BI et al. In-situ TEM investigations on the microstructural evolution of SiC fibers under ion irradiation: amorphization and grain growth. Journal of the European Ceramic Society, 43, : 1376(2023).

[4] C SONG, F YE, L CHENG et al. Long-term ceramic matrix composite for aeroengine. Journal of Advanced Ceramics, 11, : 1343(2022).

[5] C CHATEAU, L GÉLÉBART, M BORNERT et al. Modeling of damage in unidirectional ceramic matrix composites and multi-scale experimental validation on third generation SiC/SiC minicomposites. Journal of the Mechanics and Physics of Solids, 63: 298(2014).

[6] D HAN, F YE, L CHENG et al. Matrix cracking of 2D SiC/SiC composite characterized by in situ SEM and nano-CT. Ceramics International, 49, : 12508(2023).

[7] J DELAGE, E SAIZ, N AL NASIRI. Fracture behaviour of SiC/SiC ceramic matrix composite at room temperature. Journal of the European Ceramic Society, 42, : 3156(2022).

[8] S ZHAO, X ZHOU, J YU et al. Mechanical properties and in situ crack growth observation of SiC/SiC composites. Ceramics International, 40, : 7481(2014).

[12] K DETWILER, R HUNT, E OPILA. In-situ observation of micro-cracking in a SiC/BN/SiC ceramic matrix composite under tension. Open Ceramics, 14: 100366(2023).

[13] Y MIYASHITA, K KANDA, S ZHU et al. Observations of fatigue damage process in SiC/SiC composites at room and elevated temperatures. International Journal of Fatigue, 24, : 241(2002).

[15] J HOLMES, S SOMMACAL, R DAS et al. Digital image and volume correlation for deformation and damage characterisation of fibre-reinforced composites: a review. Composite Structures, 315: 116994(2023).

[16] I YAMAGUCHI. Speckle displacement and decorrelation in the diffraction and image fields for small object deformation. Optica Acta: International Journal of Optics, 28, : 1359(1981).

[17] W H PETERS, W F RANSON. Digital imaging techniques in experimental stress analysis. Optical Engineering, 21, : 427(1982).

[18] V P RAJAN, M N ROSSOL, F W ZOK. Optimization of digital image correlation for high-resolution strain mapping of ceramic composites. Experimental Mechanics, 52, : 1407(2012).

[19] F BERNACHY-BARBE, L GÉLÉBART, M BORNERT et al. Characterization of SiC/SiC composites damage mechanisms using digital image correlation at the tow scale. Composites Part A: Applied Science and Manufacturing, 68: 101(2015).

[20] C H BUMGARDNER, F M HEIM, D C ROACHE et al. Unveiling hermetic failure of ceramic tubes by digital image correlation and acoustic emission. Journal of the American Ceramic Society, 103, 2146(2020).

[21] C H BUMGARDNER, F M HEIM, D C ROACHE et al. Characterizing environment-dependent fracture mechanisms of ceramic matrix composites via digital image correlation. Journal of the American Ceramic Society, 104, : 6545(2021).

[22] M J PRESBY, M KANNAN, G N MORSCHER et al. An investigation of the end-notched flexure and end-loaded split tests applied to the mode II interlaminar fracture of a SiC/SiC ceramic matrix composite. Journal of Engineering for Gas Turbines and Power, 142: 041027(2020).

[23] N TABLEAU, Z ABOURA, K KHELLIL et al. Accurate measurement of in-plane and out-of-plane shear moduli on 3D woven SiC-SiBC material. Composite Structures, 172: 319(2017).

[24] G N MORSCHER, R MAXWELL. Monitoring tensile fatigue crack growth and fiber failure around a notch in laminate SIC/SIC composites utilizing acoustic emission, electrical resistance, and digital image correlation. Journal of the European Ceramic Society, 39, : 229(2019).

[25] P MEYER, A M WAAS. Mesh-objective two-scale finite element analysis of damage and failure in ceramic matrix composites. Integrating Materials and Manufacturing Innovation, 4, : 63(2015).

[26] P MEYER, A M WAAS. Experimental results on the elevated temperature tensile response of SiC/SiC ceramic matrix notched composites. Composites Part B: Engineering, 143: 26(2018).

[28] W G MAO, J CHEN, M S SI et al. High temperature digital image correlation evaluation of in-situ failure mechanism: an experimental framework with application to C/SiC composites. Materials Science and Engineering: A, 665: 26(2016).

[29] J TRACY, S DALY, K SEVENER. Multiscale damage characterization in continuous fiber ceramic matrix composites using digital image correlation. Journal of Materials Science, 50, : 5286(2015).

[30] K M SEVENER, J M TRACY, Z CHEN et al. Crack opening behavior in ceramic matrix composites. Journal of the American Ceramic Society, 100, : 4734(2017).

[31] J TRACY, A WAAS, S DALY. A new experimental approach for in situ damage assessment in fibrous ceramic matrix composites at high temperature. Journal of the American Ceramic Society, 98, 1898(2015).

[32] N LOVAAS. Minimizing noise and bias in DIC. https://correlated.kayako.com/article/25-minimizing-noise-and-bias-in-dic

[34] Q LI, Y CHEN, Y CHEN et al. Effects of void defects on fracture features and tensile strength of C/SiC composites: an image-based FEM study. Applied Composite Materials, 29, : 1021(2022).

[35] Y GAO, Y WANG, X YANG et al. Synchrotron X-ray tomographic characterization of CVI engineered 2D-woven and 3D-braided SiC_f/SiC composites. Ceramics International, 42, : 17137(2016).

[36] L SAUCEDO-MORA, 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(2016).

[37] Y CHEN, L GÉLÉBART, C CHATEAU et al. Analysis of the damage initiation in a SiC/SiC composite tube from a direct comparison between large-scale numerical simulation and synchrotron X-ray micro-computed tomography. International Journal of Solids and Structures, 161: 111(2019).

[38] H YANG, S XU, D ZHANG et al. In-situ tensile damage and fracture behavior of PIP SiC/SiC minicomposites at room temperature. Journal of the European Ceramic Society, 41, : 6869(2021).

[39] W GUO, Y GAO, L SUN. In-situ CT characterization of 2D woven SiC_f/SiC composite loading under compression. Science and Engineering of Composite Materials, 29, : 394(2022).

[40] C CHATEAU, L GÉLÉBART, M BORNERT et al. In situ X-ray microtomography characterization of damage in SiC_f/SiC minicomposites. Composites Science and Technology, 71, : 916(2011).

[41] A M HILMAS, K M SEVENER, J W HALLORAN. Damage evolution in SiC/SiC unidirectional composites by X-ray tomography. Journal of the American Ceramic Society, 103, : 3436(2020).

[44] D ZHANG, Y LIU, H LIU et al. Characterisation of damage evolution in plain weave SiC/SiC composites using in situ X-ray micro-computed tomography. Composite Structures, 275: 114447(2021).

[45] C YANG, S WU, S WU et al. In-situ characterization on crack propagation behavior of SiC_f/SiC composites during monotonic tensile loading. Journal of the European Ceramic Society, 42, : 6836(2022).

[46] R ZHU, Z QU, S YANG et al. An in situ microtomography apparatus with a laboratory X-ray source for elevated temperatures of up to 1000 ℃. Review of Scientific Instruments, 92, : 033704(2021).

[47] R ZHU, G NIU, Z QU et al. In-situ quantitative tracking of micro- crack evolution behavior inside CMCs under load at high temperature: a deep learning method. Acta Materialia, 255: 119073(2023).

[48] A HABOUB, H A BALE, J R NASIATKA et al. Tensile testing of materials at high temperatures above 1700 ℃ with in situ synchrotron X-ray micro-tomography. Review of Scientific Instruments, 85, : 083702(2014).

[49] H A BALE, A HABOUB, A A MACDOWELL et al. Real-time quantitative imaging of failure events in materials under load at temperatures above 1600 ℃. Nature Materials, 12, 1): 40(2013).

[50] V MAZARS, O CATY, G COUÉGNAT et al. Damage investigation and modeling of 3D woven ceramic matrix composites from X-ray tomography in-situ tensile tests. Acta Materialia, 140: 130(2017).

[51] C LIU, Y CHEN, D SHI et al. In situ investigation of failure in 3D braided SiC_f/SiC composites under flexural loading. Composite Structures, 270: 114067(2021).

[52] B P CROOM, P XU, E J LAHODA et al. Quantifying the three-dimensional damage and stress redistribution mechanisms of braided SiC/SiC composites by in situ volumetric digital image correlation. Scripta Materialia, 130: 238(2017).

[53] Y CHEN, L GÉLÉBART, C CHATEAU et al. 3D detection and quantitative characterization of cracks in a ceramic matrix composite tube using X-ray computed tomography. Experimental Mechanics, 60, : 409(2020).

[54] Y CHEN, L GÉLÉBART, C CHATEAU et al. Crack initiation and propagation in braided SiC/SiC composite tubes: effect of braiding angle. Journal of the European Ceramic Society, 40, : 4403(2020).

[55] J P FORNA-KREUTZER, J ELL, H BARNARD et al. Full-field characterisation of oxide-oxide ceramic-matrix composites using X-ray computed micro-tomography and digital volume correlation under load at high temperatures. Materials & Design, 208: 109899(2021).

[56] X GAO, B LEI, Y ZHANG et al. Identification of microstructures and damages in silicon carbide ceramic matrix composites by deep learning. Materials Characterization, 196: 112608(2023).

[57] Y DU, D ZHANG, L WANG et al. Damage mechanism characterisation of plain weave ceramic matrix composites under in-plane shear using in-situ X-ray micro-CT and deep-learning-based image segmentation. Journal of the European Ceramic Society, 44, : 142(2024).

[58] A BADRAN, D MARSHALL, Z LEGAULT et al. Automated segmentation of computed tomography images of fiber-reinforced composites by deep learning. Journal of Materials Science, 55, : 16273(2020).

[59] C U GROSSE, M OHTSU, D G AGGELIS et al. Acoustic emission testing:basics for research-applications in engineering(2022).

[60] E MAILLET, N GODIN, M R’MILI et al. Damage monitoring and identification in SiC/SiC minicomposites using combined acousto-ultrasonics and acoustic emission. Composites Part A: Applied Science and Manufacturing, 57: 8(2014).

[61] M MOEVUS, N GODIN, M R’MILI et al. Analysis of damage mechanisms and associated acoustic emission in two SiC_f/[Si-B-C] composites exhibiting different tensile behaviours. Part II: unsupervised acoustic emission data clustering. Composites Science and Technology, 68, : 1258(2008).

[62] Q SHAN, Y XUE, J HU. The anti-oxidation mechanism of SiC_f/SiC-B₄C modified with Al₂O₃ in wet atmosphere based on machine learning. Journal of the American Ceramic Society, 105, : 5853(2022).

[63] Q SHAN, Q XU, Y XUE et al. The tensile damage behavior of SiC_f/SiC-B₄C after oxidation in wet atmosphere based on acoustic emission pattern recognition. Journal of the American Ceramic Society, 104, : 4131(2021).

[64] C MUIR, N TULSHIBAGWALE, A FURST et al. Quantitative benchmarking of acoustic emission machine learning frameworks for damage mechanism identification. Integrating Materials and Manufacturing Innovation, 12, : 70(2023).

[65] G N MORSCHER. Modal acoustic emission of damage accumulation in a woven SiC/SiC composite. Composites Science and Technology, 59, : 687(1999).

[66] B SWAMINATHAN, N R MCCARTHY, A S ALMANSOUR et al. Microscale characterization of damage accumulation in CMCs. Journal of the European Ceramic Society, 41, : 3082(2021).

[67] T NOZAWA, T KOYANAGI, Y KATOH et al. Failure evaluation of neutron-irradiated SiC/SiC composites by underwater acoustic emission. Journal of Nuclear Materials, 566: 153787(2022).

[68] L YANG, Y C ZHOU, C LU. Damage evolution and rupture time prediction in thermal barrier coatings subjected to cyclic heating and cooling: an acoustic emission method. Acta Materialia, 59, : 6519(2011).

[71] S MOMON, M MOEVUS, N GODIN et al. Acoustic emission and lifetime prediction during static fatigue tests on ceramic- matrix-composite at high temperature under air.. Composites Part A: Applied Science and Manufacturing, 41, : 913(2010).

[72] S MOMON, N GODIN, P REYNAUD et al. Unsupervised and supervised classification of AE data collected during fatigue test on CMC at high temperature. Composites Part A: Applied Science and Manufacturing, 43, : 254(2012).

[73] E MAILLET. Analysis of acoustic emission energy release during static fatigue tests at intermediate temperatures on ceramic matrix composites: towards rupture time prediction. Composites Science and Technology, 72, : 1001(2012).

[74] E MAILLET, N GODIN, M R’MILI et al. Real-time evaluation of energy attenuation: a novel approach to acoustic emission analysis for damage monitoring of ceramic matrix composites. Journal of the European Ceramic Society, 34, : 1673(2014).

[75] N GODIN, P REYNAUD, G FANTOZZI. Challenges and limitations in the identification of acoustic emission signature of damage mechanisms in composites materials. Applied Sciences, 8, : 1267(2018).

[76] C E SMITH, G N MORSCHER, Z H XIA. Monitoring damage accumulation in ceramic matrix composites using electrical resistivity. Scripta Materialia, 59, : 463(2008).

[77] R MANSOUR, E MAILLET, G N MORSCHER. Monitoring interlaminar crack growth in ceramic matrix composites using electrical resistance. Scripta Materialia, 98: 9(2015).

[78] Z XIA, T SUJIDKUL, J NIU et al. Modeling of electromechanical behavior of woven SiC/SiC composites. Composites Part A: Applied Science and Manufacturing, 43, : 1730(2012).

[79] C SMITH, G MORSCHER, Z XIA. Electrical resistance of SiC/SiC ceramic matrix composites for damage detection and life-prediction: E-17375. Cleveland: NASA Glenn Research Center, 9-18(2009).

[80] M APPLEBY, G MORSCHER, D ZHU. Correlation of electrical resistance to CMC stress-strain and fracture behavior under high heat-flux thermal and stress gradients: GRC-E-DAA-TN20638. Cleveland: NASA Glenn Research Center(2015).

[81] C SIMON, F REBILLAT, G CAMUS. Electrical resistivity monitoring of a SiC/[Si-B-C] composite under oxidizing environments. Acta Materialia, 132: 586(2017).

[82] H MEI, L CHENG. Damage analysis of 2D C/SiC composites subjected to thermal cycling in oxidizing environments by mechanical and electrical characterization. Materials Letters, 59, : 3246(2005).

[85] F WANG, X TENG, X HU et al. Damage and failure analysis of a SiC_f/SiC ceramic matrix composite using digital image correlation and acoustic emission. Ceramics International, 48, : 4699(2022).

[86] Y DUAN, H QIU, T YANG et al. Flexural failure mechanism of 2.5D woven SiC_f/SiC composites: combination of acoustic emission, digital image correlation and X-ray tomography. Composites Communications, 28: 100921(2021).

[87] E MAILLET, A SINGHAL, A HILMAS et al. Combining in-situ synchrotron X-ray microtomography and acoustic emission to characterize damage evolution in ceramic matrix composites. Journal of the European Ceramic Society, 39, : 3546(2019).

[88] RASSI J EL, A L HEGEMAN, G N MORSCHER. A ply-level electrical resistance approach to monitor crack evolution in a laminate SiC/SiC composites. Journal of the European Ceramic Society, 42, : 5355(2022).

[89] T WHITLOW, E JONES, C PRZYBYLA. In-situ damage monitoring of a SiC/SiC ceramic matrix composite using acoustic emission and digital image correlation. Composite Structures, 158: 245(2016).

[90] C SIMON, F REBILLAT, V HERB et al. Monitoring damage evolution of SiC_f/[SiBC]_m composites using electrical resistivity: crack density-based electromechanical modeling. Acta Materialia, 124: 579(2017).

[91] G N MORSCHER, N A GORDON. Acoustic emission and electrical resistance in SiC-based laminate ceramic composites tested under tensile loading. Journal of the European Ceramic Society, 37, : 3861(2017).

[92] M P APPLEBY, D ZHU, G N MORSCHER. Mechanical properties and real-time damage evaluations of environmental barrier coated SiC/SiC CMCs subjected to tensile loading under thermal gradients. Surface and Coatings Technology, 284: 318(2015).

[93] C BROCKMAN, C SWITZER, A ALMANSOUR et al. High-temperature mechanical tensile testing of unidirectional SiC_f/SiC composites using a versatile lamp furnace. 11th International Conference on High Temperature Ceramic Matrix Composites, Jeju(2023).