Finite-Temperature Ferroelectric Phase Transitions from Machine-Learned Force Fields

Abstract

Simulating finite temperature phase transitions from first-principles is computationally challenging. Recently, molecular dynamics (MD) simulations using machine-learned force fields (MLFFs) have opened a new avenue for finite-temperature calculations with near-first-principles accuracy. Here we use MLFFs, generated using on-the-fly training, to investigate structural phase transitions in four of the most well-studied ferroelectric oxides; BaTiO3, PbTiO3, LiNbO3 and BiFeO3. Only using the 0 K ground state structure as input for the training, the resulting MLFFs can qualitatively predict all the main structural phases and phase transitions, while the quantitative results are sensitive to the choice of exchange correlation functional with PBEsol found to be more robust than LDA and r2SCAN. MD simulations also reproduce the experimentally observed order-disorder character of Ti displacements in BaTiO3, the abrupt first order transitions of BiFeO3 and PbTiO3, and the mixed order-disorder and displacive character of the ferroelectric transition in LiNbO3. Finally, we discuss the potential and limitations of using MLFFs for simulating ferroelectric phase transitions.

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