# Contrasting the dynamics of elastic and non-elastic deformations across   an experimental colloidal Martensitic transition

**Authors:** Saswati Ganguly, Priti S. Mohanty, Peter Schurtenberger, Surajit, Sengupta, Anand Yethiraj

arXiv: 1705.00741 · 2017-05-03

## TL;DR

This study introduces a framework to distinguish elastic and non-elastic deformations in real-space experiments of Martensitic transitions in colloidal crystals, revealing detailed particle dynamics and the coexistence of different crystallite formation mechanisms.

## Contribution

It provides a novel method to identify non-affine fluctuations during phase transitions in colloidal systems, enhancing understanding of transformation mechanisms.

## Key findings

- Non-affine fluctuations signal the onset of the transition.
- Particle rearrangements favor non-affine modes during transformation.
- Different displacement modes govern the formation of BCO crystallites.

## Abstract

We present a framework to segregate the roles of elastic and non-elastic deformations in the examination of real-space experiments of solid-solid Martensitic transitions. The Martensitic transformation of a body-centred-tetragonal(BCT) to a body-centred-orthorhombic(BCO) crystal structure has been studied in a model system of micron-scale ionic microgel colloids. Non-affine fluctuations, i.e., displacement fluctuations that do not arise from purely elastic(affine) deformations, are detected in particle configurations acquired from the experiment. Tracking these fluctuations serves as a highly sensitive tool in signaling the onset of the Martensitic transition and precisely locating particle rearrangements occurring at length scales of a few particle diameters. Particle rearrangements associated with non-affine displacement modes become increasingly favorable during the transformation process. The nature of the displacement fluctuation modes that govern the transformation are shown to be different from those predominant in an equilibrium crystal. We show that BCO crystallites formed through shear may, remarkably, co-exist with those resulting from local rearrangements within the same sample.

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/1705.00741/full.md

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Source: https://tomesphere.com/paper/1705.00741