A crystallographic model of the {557} habit planes in low-carbon martensitic steels

TL;DR

This paper develops a crystallographic model for {557} habit planes in low-carbon martensitic steels, combining theoretical calculations with EBSD experiments to identify the habit planes of blocks within martensite variants.

Contribution

It introduces a new averaging method for distortion matrices and demonstrates that {575} planes are the habit planes of blocks, clarifying previous ambiguities.

Findings

{575} planes are the habit planes of blocks.

The model is simple and parameter-free.

EBSD confirms the {575} habit planes in steels.

Abstract

Low-alloy steels are constituted of twenty-four variants of lath martensite that exhibit gradients of orientations from Kurdjumov-Sachs (KS) to Nishiyama-Wassermann (NW). They are structured into four packets on each of the common close-packed plane {111}fcc// {110}bcc; and each packet is composed of three blocks constituted by pairs of low-misoriented variants. The habit planes reported in literature for this type of martensite are {557}fcc, but it is not clear whether they correspond to the laths or to the blocks. In this paper, we present crystallographic calculations proving that the average of the two KS distortions associated with the variants in a block is exactly a NW distortion. A new method of averaging distortion matrices was introduced for this purpose. It is also shown that the {575}fcc planes are let untilted by this NW distortion, and are thus good theoretical candidates for the observed habit planes. The predicted {575}fcc planes, however, do not contain any of the common close-packed directions of the two variants in the block, which is in apparent contradiction with the current view. In order to clarify this point, some Electron BackScatter Diffraction (EBSD) maps were acquired on different low-carbon steels; the prior austenitic grains were automatically reconstructed and the traces of the habit planes predicted by the different models were analyzed and compared to the morphologies. This experimental work shows that {575}fcc planes are the habit plane of the blocks, and that the habit plane of one block often dominates the others, which impedes to discriminate the different models. The advantages of our model are its simplicity, the absence of fitting parameters, and the symmetric role played by the variants the blocks.