Application-oriented strain-hardening engineering of high-manganese steels

TL;DR

This paper discusses a computational approach for designing high-manganese steels with tailored mechanical properties by controlling deformation mechanisms through alloy selection and processing techniques, advancing strain-hardening engineering.

Contribution

It introduces an integrated computational materials engineering method combining alloy selection and process design to optimize the strain-hardening behavior of high-manganese steels for specific applications.

Findings

Alloy selection via stacking-fault energy calculations enables targeted activation of deformation mechanisms.

Processing techniques like thermo-mechanical treatment can tailor mechanical properties post-manufacturing.

The approach facilitates prediction and design of mechanical properties based on processing conditions.

Abstract

The outstanding mechanical properties of high-manganese steels (HMnS) are a result of their high strain-hardenability. That is facilitated by strong suppression of dynamic recovery, predominant planar glide, and the activation of additional deformation mechanisms, such as transformation-induced plasticity (TRIP) and twinning-induced plasticity (TWIP). However, depending on the final application, strongly differing requirements on the mechanical properties of HMnS are of relevance. In order to design HMnS for specific applications, multi-scale material simulation under consideration of the processing conditions that allows for prediction of the final mechanical properties is required, i.e. strain-hardening engineering based on integrated computational materials engineering (ICME). In this work, we present an approach that employs alloy selection by stacking-fault energy calculations, which enables activation/suppression of specific deformation mechanisms. Tailored manufacturing, e.g. by thermo-mechanical treatment, severe plastic deformation or additive manufacturing, provides possibilities to make use of the strain-hardenability during and after processing to define the mechanical properties. A computational approach for alloy and process design will be discussed.