English

Shoot from the HIP: Hessian Interatomic Potentials without derivatives

Machine Learning 2025-12-16 v2 Chemical Physics Computational Physics

Abstract

Fundamental tasks in computational chemistry, from transition state search to vibrational analysis, rely on molecular Hessians, which are the second derivatives of the potential energy. Yet, Hessians are computationally expensive to calculate and scale poorly with system size, with both quantum mechanical methods and neural networks. In this work, we demonstrate that Hessians can be predicted directly from a deep learning model, without relying on automatic differentiation or finite differences. We observe that one can construct SE(3)-equivariant, symmetric Hessians from irreducible representations (irrep) features up to degree ll=2 computed during message passing in graph neural networks. This makes HIP Hessians one to two orders of magnitude faster, more accurate, more memory efficient, easier to train, and enables more favorable scaling with system size. We validate our predictions across a wide range of downstream tasks, demonstrating consistently superior performance for transition state search, accelerated geometry optimization, zero-point energy corrections, and vibrational analysis benchmarks. We open-source the HIP codebase and model weights to enable further development of the direct prediction of Hessians at https://github.com/BurgerAndreas/hip

Cite

@article{arxiv.2509.21624,
  title  = {Shoot from the HIP: Hessian Interatomic Potentials without derivatives},
  author = {Andreas Burger and Luca Thiede and Nikolaj Rønne and Varinia Bernales and Nandita Vijaykumar and Tejs Vegge and Arghya Bhowmik and Alan Aspuru-Guzik},
  journal= {arXiv preprint arXiv:2509.21624},
  year   = {2025}
}

Comments

https://github.com/BurgerAndreas/hip

R2 v1 2026-07-01T05:57:17.416Z