https://orcid.org/0000-0002-3354-646X
References
- Subramanian R, Metoki A, Alejandro CV, et al. Small crack growth behaviors of a polycrystalline Ni-based superalloy under temperature gradient creep condition. Mech Eng Lett. 2015;1:15–00461–15–00461.
- Rajivandhi S, Metoki A, Yamagishi S, et al., Creep crack growth behaviors of gas turbine blade under a significant temperature gradient conditions. Proceedings of International Gas Turbine Congress; pp.449–455, Tokyo: Japan; 2015.
- Walters DJ, Hales R. An extensometer for creep-fatigue testing at elevated temperatures and low strain ranges (±0.2 percent< δ∊< 1.0 per cent). J Strain Anal. 1981;16(2):145–147.
- Gossick BR. Design of extensometer for creep studies. Rev Sci Instrum. 1954;25(9):907–909.
- Lin J, Hayhurst DR, Dyson BF. A new design of the uniaxial creep test piece with slit extensometer ridges for improved accuracy of strain measurement. Int J Mech Sci. 1993;35(1):63–78.
- Bueno LDO, Sordi VL, Marino L. Constant load creep data in air and vacuum on 2.25Cr-1Mo steel from 600 °C to 700 °C. Mater Res. 2005;8(4):401–408.
- Sakanashi Y, Gungor S, Bouchard PJ, Creep deformation measurement of 316H stainless steel multi-pass welded joints using digital image correlation. International Conference on Integrity of High Temperature Welds; London; 2012.
- Sakanashi Y, Gungor S, Forsey AN, et al. Measurement of creep deformation across welds in 316H stainless steel using digital image correlation. Exp Mech. 2017;57(2):231–244.
- Corcoran J, Hooper P, Davies C, et al. Creep strain measurement using a potential drop technique. Int J Mech Sci. 2016;110:190–200.
- Corcoran J, Davies CM. Monitoring power-law creep using the failure forecast method. Int J Mech Sci. 2018;140:179–188.
- Oh C, Han C, Park N, et al., Creep mechanism fractography analysis of SnPb eutectic solder joint failure. IEEE European Microelectronics and Packaging Conference; Rimini, Italy; 2009.
- Garg M, Salaria B, Gupta V. Effect of thermal gradient on steady state creep in a rotating disc of variable thickness. Procedia Eng. 2013;55:542–547.
- Lee WS, Chen LW, Yeh LT. The influence of strain rate and temperature on the deformation behaviour of 63Sn/37Pb and 60Sn/40Pb solder alloys. Mater Trans. 2001;42(4):686–690.
- Shi XQ, Wang ZP, Yang QJ, et al. Creep behavior and deformation mechanism map of Sn-Pb eutectic solder alloy. J Eng Mater Technol. 2003;125(1):81–88.
- Tsukada Y, Nishimura H, Yamamoto H, et al., A strain rate ratio approach for assessing creep-fatigue life of 63Sn-37Pb solder under shear loading. J Electron Packag. 2005;407–414.
- Sasaki K, Kobayashi T, Ohguchi KI. Experimental observation of correlation between creep and uniaxial ratchetting of Sn∕37Pb and Sn∕3Ag∕0.5Cu solder alloys. J Electron Packag. 2007;129(1):82–89.
- Shi XQ, Wang ZP, Zhou W, et al. A new creep constitutive model for eutectic solder alloy. J Electron Packag. 2002;124(2):85–90.
- Dieter GE, Bacon D. Mechanical metallurgy. McGraw-Hill: London; 1988.
- Zhang JP, Fu QG, Qu JL. Effect of temperature gradient on the erosion behavior of SiC coating for carbon/carbon composites in a combustion environment. Ceram Int. 2016;42(16):18411–18417.
- Gao ZZ, Zhi XZ, Hou NX, et al. Deformation and failure mechanisms of single crystal superalloy under temperature gradient. Theor Appl Fract Mech. 2011;56(3):180–187.
- Hou NX, Wen ZX, Yue ZF. Tensile and fatigue behavior of thin-walled cylindrical specimens under temperature gradient condition. J Mater Sci. 2008;43(6):1933–1938.
- Logsdon WA, Liaw PK, Burke MA. Fracture behavior of 63Sn-37Pb solder. Eng Fract Mech. 1990;36(2):183–218.
- Avner SH. Introduction to physical metallurgy. 2nd ed ed. McGraw-Hill: New York; 1997.