[1] Yang Y Q,Dudek H,Kumpfert J. TEM investigations of the fiber/matrix interface in SCS-6 SiC/Ti-25Al-10Nb-3V-1Mo composites. Composites Part A, 1998, 29A:1235-1241.
[2] Yang Y Q, Dudek H J. Interface stability in SCS-6 SiC/Super α2.Composites Scripta Material, 1997, 37(4): 503-510.
[3] Yang Y Q,Dudek H J, Kumpfert J. Interfacial reaction and stability of SCS-6 SiC/Ti-25Al-10Nb-3V-1Mo. Composites Materials Science and Engineering, 1998, 246: 213-220.
[4] Yang Y Q,Werner A,Dudek H J, et al.TEM investigations of interfacial processes in SCS-6 SiC/TiB2/Superα2. Composites Part A, 1999, 30: 1209-1244.
[5] Yang Y Q, Zhu Y, Ma Z J. Formation of interfacial reaction products in SCS-6 SiC/Ti2AlNb composites. Scripta Materialia, 2004, 51: 385-389.
[6] Smith P R, Rhodes C G, Revelos W C. Interfacial Evalution in a Ti-25Al-17Nb/SCS-6 Composite. // Lin R Y, Arsenault R J, Martins G P, et al. Interfaces in Metal-Ceramics Composites. PA: The Minerals, Metals and Materials Scoiety, 1990:907-923.
[7] Brett A, Bednarcyk, Steven M, et al. A new local failure model with application to the longitudinal tensile behavior of continuously reinforced titanium composites. NASA/TM--2000-210027.
[8] Quast J P, Boehlert C J. The out-of-phase thermomechanical fatigue behavior of Ultra SCS-6/Ti-24Al-17Nb-xMo (at.%) metal matrix composites. International Journal of Fatigue, 2009, 32: 610-620.
[9] Chatterjee A, Roessler J R, Brown L E. Microstructure and mechanical properties of ultra SCS fiber reinforced orthorhombic Ti-22Al-26Nb composites. Structural Intermetallics, 1997, 32(11):905-911.
[10] Her Y C, Wang P C, Yang J M. Fatigue crack initiation and multiplication of unnotched titanium matrix composites. Acta mater, 1998, 46(18):6645-6659.
[11] Quast J P, Boehlert C J. The effect of molybdenum on the microstructure and creep behavior of Ti-24Al-17Nb-xMo alloys and Ti-24Al-17Nb-xMo SiC-fiber composites. Journal of Materials Science, 2008, 43(13):4411-4422.
[12] Jeng S M, Yang J M, Graves J A. Effect of fiber coating on the mechanical behavior of SiC fiber-reinforced titanium aluminide composites. J. Mater. Res. 1993, 8: 905-916.
[13] Yang Y Q, Dudek H, Kumpfert J., TEM Investigations of the fiber reinforced matrix interface in SCS-6 SiC/Ti-25Al-10Nb-3V-1Mo Composites. Composites Part A: Applied Science and Manufacturing, 1998,29(9-10): 1235-1241.
[14] Lü Xianghong, Yang Yanqing, MA Zhijun. Kinetics and mechanism of interfacial reaction in SCS-6 SiC continuous fiber-reinforced Ti-Al intermetallic matrix composites.Trans. Nonferrous Met. Soc. China, 2006,16: 77-83.
[15] Yang Y Q, Zhu Y, Ma Z J. Formation of interfacial reaction products in SCS-6 SiC/Ti2AlNb composites. Scripta.Mater, 2004, 51(11):385-389.
[16] Karl U, Kainer. Metal Matrix Composites. Weinheim: Woley-VCH Verlag GmbH & Co. KGaA, 2006:38-39.
[17] Gall K, Sehitoglu H, Kadioglu Y. Plastic zones and fatigue-crack closure under plane-strain double slip. Metall Mater Trans A, 1996, 27A:3491-3502.
[18] Her Y C, Wang P C, Yang J M. Interface-controlled fatigue cracking of SCS6/Ti22Al23Nb “orthorhombic” titanium aluminide composite. Metall.Mater. Trans.A, 1998, 29(11):2737-2746.
[19] Ochiai S, Hojo M, Mototsugu Mesoscopic T. Mechanical interactions between fiber and cracked coating layer and their influences on fiber strength. Composites Part A, 1999, 30:451-461.
[20] Ochiai S, Hojo M. Effects of pre-existent crack in double and gradient coatings on the crack extension into fibre and interfacial debonding. Journal of Materials Science, 1998, 33:347-355.
[21] Greaves I, Yates J R, Atkinson H V. The role of the interface in the initiation of fatigue cracks in SCS-6/titanium MMCs. Composites, 1994, 25(7): 692-697.
[22] Cardona D C, Barney C, Bowen P. Micro-modelling of effective stress intensities for bridged cracks in fibre-reinforced titanium metal-matrix composites. Composites, 1993, 24(2):122-128.
[23] Watson M C, Clyne T W. Reaction-induced changes in interfacial and macroscopic mechanical properties of SiC monofilament-reinforced titanium. Composites, 1993, 24(3): 222-228.