Neutron-diffraction study of martensitic transformation in austenitic stainless steel under low-cycling tensile–compressive loading

被引：0

作者：

Y.V. Taran

M.R. Daymond

D. Eifler

J. Schreiber

机构：

[1] Frank Laboratory of Neutron Physics,

[2] Joint Institute for Nuclear Research,undefined

[3] 141 980 Dubna,undefined

[4] Moscow Region,undefined

[5] Russia,undefined

[6] ISIS,undefined

[7] Rutherford Appleton Laboratory,undefined

[8] Chilton,undefined

[9] Oxon OX11 0QX,undefined

[10] UK,undefined

[11] DMS,undefined

[12] University of Kaiserslautern,undefined

[13] 67 653 Kaiserslautern,undefined

[14] Germany,undefined

[15] EADQ,undefined

[16] Fraunhofer Institute for Nondestructive Testing,undefined

[17] 01326 Dresden,undefined

[18] Germany,undefined

来源：

Applied Physics A | 2002年 / 74卷

关键词：

PACS: 61.12.-q; 81.30.Kf; 81.40.Jj;

D O I：

暂无

中图分类号：

学科分类号：

摘要：

The fatigue behaviour of austenitic stainless steel, in which a martensitic phase is formed due to plastic deformation, is of some interest for practical reasons. Earlier, we reported the results of the first stage of the in situ stress-rig experiment on the ENGIN instrument at the ISIS facility, with samples from steel X6CrNiTi1810 subjected to different tensile–compressive loading cycles at a frequency of 5 Hz. This paper describes the results of the second stage of the experiment in which a series of samples subjected to 0.5 Hz was studied. Information about the mechanical properties of the austenitic matrix and the martensitic precipitates is obtained from the experimental mechanical and neutron-diffraction data.

引用

页码：s1391 / s1393

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