General Learning of the Electric Response of Inorganic Materials

Abstract

We introduce MACE-Field, a field-aware, O(3)-equivariant interatomic potential that learns a single electric enthalpy functional F(\ R\, E) and obtains P, Z*, and α by exact differentiation. A uniform field couples to latent equivariant features inside the MACE backbone, while the scalar energy readout preserves Maxwell reciprocity, the acoustic sum rule, and crystal tensor symmetries by construction. Because this coupling is a plug-in on top of standard MACE, existing energy/force foundation models can be upgraded to become field-aware. Benchmarked against semilocal DFT/DFPT reference data, a directly trained cross-chemistry ferroelectric model reproduces the same-branch Berry-phase and spontaneous polarisations across diverse inorganic crystals. Starting from the multihead foundation model mace-mp-mh-0 and its OMAT-PBE head, joint fine-tuning on dielectric, ferroelectric, and replay data yields MACE-Field-MH-0 foundation models, which predict Z*, α, derived dielectric constants, and cross-chemistry polarisation trends with fidelity that captures branch-resolved polarisation and spontaneous-polarisation, while retaining strong force-field accuracy. Further, single-material MACE-Field models and MACE-Field-MH-0 reproduce BaTiO3 hysteresis loops and α-quartz infrared, Raman, and dielectric spectra from finite-field molecular dynamics, comparable to DFPT. These results show that a simple, physics-informed field coupling can endow atomistic foundation models with transferable dielectric and ferroelectric response, while targeted single-material training remains advantageous for the most quantitative spectroscopic predictions.