Abstract
Catalyzed by enormous success in the industrial sector, many research programs have been exploring data-driven, machine learning approaches. Performance can be poor when the model is extrapolated to new regions of chemical space, e.g., new bonding types, new many-body interactions. Another important limitation is the spatial locality assumption in model architecture, and this limitation cannot be overcome with larger or more diverse datasets. The outlined challenges are primarily associated with the lack of electronic structure information in surrogate models such as interatomic potentials. Given the fast development of machine learning and computational chemistry methods, we expect some limitations of surrogate models to be addressed in the near future; nevertheless spatial locality assumption will likely remain a limiting factor for their transferability. Here, we suggest focusing on an equally important effort—design of physics-informed models that leverage the domain knowledge and employ machine learning only as a corrective tool. In the context of material science, we will focus on semi-empirical quantum mechanics, using machine learning to predict corrections to the reduced-order Hamiltonian model parameters. The resulting models are broadly applicable, retain the speed of semiempirical chemistry, and frequently achieve accuracy on par with much more expensive ab initio calculations. These early results indicate that future work, in which machine learning and quantum chemistry methods are developed jointly, may provide the best of all worlds for chemistry applications that demand both high accuracy and high numerical efficiency.
Original language | English |
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Article number | 110901 |
Journal | Journal of Chemical Physics |
Volume | 159 |
Issue number | 11 |
DOIs | |
State | Published - Sep 21 2023 |
Externally published | Yes |
Funding
The authors gratefully acknowledge Dr. James P. Stewart for his insightful and stimulating discussions during his visit. The work at Los Alamos National Laboratory (LANL) was supported by the LANL Directed Research and Development Funds (LDRD) and performed in part at the Center for Nonlinear Studies (CNLS) and the Center for Integrated Nanotechnologies (CINT), a US Department of Energy (DOE) Office of Science user facility at LANL. N.F. and M.K. acknowledges the financial support from the Director's Postdoctoral Fellowship at LANL funded by LDRD. K.B. and S.T. acknowledge support from the US DOE, Office of Science, Basic Energy Sciences, Chemical Sciences, Geosciences, and Biosciences Division under Triad National Security, LLC (“Triad”) Contract No. 89233218CNA000001 (FWP: LANLE3F2). This research used resources provided by the LANL Institutional Computing (IC) Program. LANL is managed by Triad National Security, LLC, for the US DOE’s NNSA, under Contract No. 89233218CNA000001. O.I. acknowledges financial support from NSF under the CCI Center for Computer Assisted Synthesis Grant No. CHE-2202693.