Machine learning reveals memory of the parent phases in ferroelectric relaxors Ba(Ti1-x,Zrx)O3
Abstract
Machine learning has been establishing its potential in multiple areas of condensed matter physics and materials science. Here we develop and use an unsupervised machine learning workflow within a framework of first-principles-based atomistic simulations to investigate phases, phase transitions, and their structural origins in ferroelectric relaxors, Ba(Ti1-x,Zrx)O3. We first demonstrate the applicability of the workflow to identify phases and phase transitions in the parent compound, a prototypical ferroelectric BaTiO3. We then apply the workflow on Ba(Ti1-x,Zrx)O3, with x≤0.25 to reveal (i) that some of the compounds bear a subtle memory of BaTiO3, phases beyond the point of the pinched phase transition, which could contribute to their enhanced electromechanical response; (ii) the existence of peculiar phases with delocalized precursors of nanodomains -- likely candidates for the controversial polar nanoregions; and (iii) nanodomain phases for the largest concentrations of x
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