The low-cycle fatigue (LCF) behaviour of SUS304-HP austenitic stainless steel was
investigated systematically using tension-compression cycling under fully reversed total …

A complete understanding of 'cyclic plasticity induced transformation'of austenitic stainless
steels is documented in this article through different experiments, their critical analysis and …

Strain-controlled low cycle fatigue tests have been conducted in air between 298–873 K to
ascertain the influence of temperature on LCF behaviour of nitrogen-alloyed type 316L …

Total strain controlled low cycle fatigue tests on 316L (N) stainless steel have been
conducted in air at various strain rates in the temperature range of 773–873K to identify the …

High-temperature low cycle fatigue (LCF) is influenced by various time-dependent
processes such as creep, oxidation, phase transformations and dynamic strain ageing …

Dislocation structures in two heats of 316L austenitic stainless steels, cyclically strained at
room temperature with constant plastic strain amplitude over a wide interval, were studied …

It remains an intricate problem how to enhance low-cycle fatigue (LCF) performance, in the
premise of guaranteeing a relatively high strength (or cyclic stress) which is vital to long-time …

Low cycle fatigue (LCF) at elevated temperatures is known to be influenced by time-
dependent processes like creep, oxidation and metallurgical instabilities. Another time …

An endurance against multiaxial fatigue of 316L steel is studied. A fatigue life curve of
torsional mode is substantially shifted to longer fatigue lives while tension/compression …

This article is concerned with the cyclic properties of 316L-type austenitic stainless at 300
and 77 K. The role of nitrogen alloying and of the temperature decrease is examined during …