13th International Conference on Fracture June 16-21, 2013, Beijing, China References [1] C. Mareau, V. Favier, B. Weber, A. Galtier, and M. Berveiller. Micromechanical modeling of the interactions between the microstructure and the dissipative deformation mechanisms in steels under cyclic loading. International Journal of Plasticity, 2012. [2] G. Fargione, A. L. Geraci, G. La Rosa, and A. Risitano. Rapid determination of the fatigue curve by the thermographic method. International Journal of Fatigue, 24(1):11–19, 2002. [3] M. P. Luong. Fatigue limit evaluation of metals using an infrared thermographic technique. Mechanics of Materials, 28(1-4):155–163, 1998. [4] M. Amiri and M. M. Khonsari. Life prediction of metals undergoing fatigue load based on temperature evolution. Materials Science and Engineering A, 527(6):1555–1559, 2010. [5] X. G. Wang, V. Crupi, X. L. Guo, and Y. G. Zhao. Quantitative thermographic methodology for fatigue assessment and stress measurement. International Journal of Fatigue, 32(12):1970–1976, 2010. [6] C. Doudard, S. Calloch, P. Cugy, A. Galtier, and F. Hild. A probabilistic two-scale model for high-cycle fatigue life predictions. Fatigue and Fracture of Engineering Materials and Structures, 28(3):279–288, 2005. [7] T. Boulanger, A. Chrysochoos, C. Mabru, and A. Galtier. Calorimetric analysis of dissipative and thermoelastic effects associated with the fatigue behavior of steels. International Journal of Fatigue, 26(3):221–229, 2004. [8] G. Meneghetti and M. Ricotta. The use of the specific heat loss to analyse the low- and high-cycle fatigue behaviour of plain and notched specimens made of a stainless steel. Engineering Fracture Mechanics, 2011. [9] N. Connesson, F. Maquin, and F. Pierron. Experimental energy balance during the first cycles of cyclically loaded specimens under the conventional yield stress. Experimental Mechanics, 51(1):23–44, 2011. [10] J. P. Strizak and L. K. Mansur. The effect of mean stress on the fatigue behavior of 316 ln stainless steel in air and mercury. Journal of Nuclear Materials, 318(SUPPL):151–156, 2003. [11] F. Maquin and F. Pierron. Heat dissipation measurements in low stress cyclic loading of metallic materials: From internal friction to microplasticity. Mechanics of Materials, 41(8):928–942, 2009. [12] N. Connesson, F. Maquin, and F. Pierron. Dissipated energy measurements as a marker of microstructural evolution: 316l and dp600. Acta Materialia, 59(10):4100–4115, 2011. [13] G. Meneghetti. Analysis of the fatigue strength of a stainless steel based on the energy dissipation. International Journal of Fatigue, 29(1):81–94, 2007. 10
RkJQdWJsaXNoZXIy MjM0NDE=