Tensor Train Optimization for Conformational Sampling of Organic Molecules

10 December 2024, Version 2
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

Exploring the conformational space of molecules remains a challenge of fundamental importance to quantum chemistry: identification of relevant conformers at ambient conditions enables predictive simulations of almost arbitrary properties. Here, we propose a novel approach to enable conformational sampling of large organic molecules where the combinatorial explosion of possible conformers prevents the use of a brute-force systematic conformer search. We employ tensor trains as a highly efficient dimensionality reduction algorithm, effectively reducing the scaling from exponential to polynomial. In our approach, the conformational search is expressed as global energy minimization task in a high-dimensional grid of dihedral angles. Dimensionality reduction is achieved through a tensor train representation of the high-dimensional torsion space. The performance of the approach is assessed on a variety of drug-like molecules in direct comparison to the state-of-the-art metadynamics based conformer rotamer ensemble sampling tool (CREST). The comparison shows significant acceleration of up to an order of magnitude, while maintaining comparable accuracy. More importantly, the presented approach allows treatment of larger molecules than typically accessible with metadynamics.

Keywords

Conformer search
Tensor networks
Global optimization

Supplementary materials

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Supporting information
Description
Description of the molecular graph generation to define the tensor train representaion. Additional figures showing chemical structures of benchmark compounds. Additional results for Astex set and testing of optimum settings. Additional results for ala oligomers and ensemble comparisons.
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