Litcius/Paper detail

PET-MAD as a lightweight universal interatomic potential for advanced materials modeling

Arslan Mazitov, Filippo Bigi, Matthias Kellner, Paolo Pegolo, Davide Tisi, Guillaume Fraux, Sergey N. Pozdnyakov, Philip Loche, Michele Ceriotti

2025Nature Communications33 citationsDOIOpen Access PDF

Abstract

Machine-learning interatomic potentials have greatly extended the reach of atomic-scale simulations, offering the accuracy of first-principles calculations at a fraction of the cost. Leveraging large quantum mechanical databases and expressive architectures, recent universal models deliver qualitative accuracy across the periodic table but are often biased toward low-energy configurations. We introduce PET-MAD, a generally applicable interatomic potential trained on a dataset combining stable inorganic and organic solids, systematically modified to enhance atomic diversity. Using a moderate but thoroughly consistent level of electronic-structure theory, we assess PET-MAD's accuracy on established benchmarks and advanced simulations of six materials. Despite the small training set and lightweight architecture, PET-MAD is competitive with the state-of-the-art machine-learned interatomic potentials for inorganic solids, while also being reliable for molecules, organic materials, and surfaces. It is stable and fast, enabling the near-quantitative study of thermal and quantum mechanical fluctuations, functional properties, and phase transitions out of the box. It can be efficiently fine-tuned to deliver full quantum mechanical accuracy with a minimal number of targeted calculations.

Topics & Concepts

Interatomic potentialComputer scienceQuantumSet (abstract data type)Table (database)Molecular dynamicsStatistical physicsThermalComputational scienceMultiscale modelingQuantum chemicalMaterials sciencePhase (matter)Quantum dotAlgorithmNanotechnologyDensity functional theoryPhase transitionQuantum computerLennard-Jones potentialMachine Learning in Materials ScienceAdvanced Physical and Chemical Molecular InteractionsInorganic Chemistry and Materials