Scalable parallel algorithm for graph neural network interatomic potentials in molecular dynamics simulations

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• Precipitate phase selection and grain boundary morphology in Cu-Ni-Si-Mn alloys: A machine-learning interatomic potential study cond-mat.mtrl-sci · 2026-06-08 · conditional · none · ref 51

  MLIP simulations show that Mn promotes incoherent interfaces with the G-phase leading to film-like GB precipitates, while Ni2Si forms irregular shapes due to coherent interfaces that develop repulsive regions.

• GFFMERGE: Efficient Merging of Graph Neural Force Fields and Beyond cs.LG · 2026-06-02 · unverdicted · none · ref 58

  GFFMERGE formulates GNN force field merging as a convex embedding-alignment problem with an analytical solution, recovering near joint-training performance on MD17, MD22, LiPS20 and other benchmarks while delivering 5-27x speedups.

• Speculative Sampling For Faster Molecular Dynamics cs.LG · 2026-06-01 · unverdicted · none · ref 61

  LSD extends speculative sampling to second-order Langevin dynamics, achieving 3-9x speedup in MD while exactly sampling from the target distribution without relative error.

• Teaching Molecular Dynamics to a Non-Autoregressive Ionic Transport Predictor cs.LG · 2026-05-10 · unverdicted · none · ref 2

  Non-autoregressive ionic transport predictor learns dynamics from auxiliary trajectory data during training only, achieving over 200x speedup versus autoregressive models and lower error than non-autoregressive baselines on both dataset types.

• Compact SO(3) Equivariant Atomistic Foundation Models via Structural Pruning cs.LG · 2026-05-09 · unverdicted · none · ref 3

  Structural pruning of SO(3) equivariant atomistic models from large checkpoints yields 1.5-4x fewer parameters and 2.5-4x less pre-training compute than small models trained from scratch, while outperforming them on most Matbench Discovery metrics and downstream tasks.

• Density diversity in training data governs thermodynamic transferability of machine learning interatomic potentials physics.chem-ph · 2026-05-07 · unverdicted · none · ref 22

  Density diversity in training data is the key factor for making machine learning interatomic potentials transferable across thermodynamic states, outperforming temperature diversity.

• Bayesian E(3)-Equivariant Interatomic Potential with Iterative Restratification of Many-body Message Passing cs.LG · 2025-10-03 · unverdicted · none · ref 46

  Bayesian E(3)-equivariant MLPs with joint energy-force NLL loss achieve competitive accuracy while enabling uncertainty-guided active learning, OOD detection, and calibration.

• Fine-tuning MLIP foundation models: strategies for accuracy and transferability physics.chem-ph · 2026-06-10 · unverdicted · none · ref 6

  Systematic tests show naive fine-tuning excels for single-task accuracy while multihead replay best preserves out-of-distribution robustness in MLIP adaptation.