Phase decomposition in an Fe-Cr alloy at 402 deg C: M\"ossbauer spectroscopic study

TL;DR

This study investigates phase separation in Fe-Cr alloys at 402°C using Mossbauer spectroscopy, revealing kinetic parameters, Cr concentration, and magnetic texture differences between strained and strain-free samples.

Contribution

It provides detailed kinetic and compositional analysis of phase separation in Fe-Cr alloys using Mossbauer spectroscopy, highlighting effects of strain on these processes.

Findings

Activation energy differs between strained and strain-free samples.

Cr concentration in Fe-rich phase varies with strain state.

Magnetic texture shows measurable differences between samples.

Abstract

Phase separation in strained and strain-free samples of Fe84.85Cr15.15 induced by an isothermal annealing at 402 deg C up to 3888 h was studied by means of the Mossbauer spectroscopy. The measured Fe-site spectra were analyzed with two different procedures viz. a hyperfine field distribution and a two-shell superposition methods. Information relevant to the kinetics of the separation process, concentration of Cr in Fe-rich phase, short-range ordering and magnetic texture was obtained based on values of spectral parameters. In particular, the following quantities pertinent to the kinetics were found: the activation energy, equal to 1666 kJ per mol for the strained sample, and to 1388 kJ per mol for the strain-relaxed one, the Avrami exponent n=2.5(2) for both samples, the rate constant equal to 0.0011(1) for the strained and to 0.0028(1) per hour for the strained-free samples, respectively. The concentration of Cr in the Fe-rich phase was revealed to be 11.6(4) at. % for the strained sample, and to 13.2(4) at.% for the strain-free one. Significant differences in the values of the short-range parameters were revealed for the two samples. An average angle between the magnetization vector and the normal to the sample surface was equal to 52.7 deg for the strained sample, and to 57.5 deg for the strain-relaxed one.