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A Transferable Machine Learning Approach to Predict Optimized Orbitals for Electronic Structure Problems

Quantum Physics 2026-05-07 v1

Abstract

Variational quantum eigensolver ans\"atze hold considerable promise for ground-state energy calculations on near-term quantum hardware, yet most promising ansatz designs currently strongly depend on how well the molecular orbital basis captures the electronic correlation of the system. Computing optimized orbital coefficients via classical routines is computationally expensive and must be performed independently for each molecular geometry -- a bottleneck that limits scalability across chemical space. We present a graph neural network framework that predicts optimized orbital coefficients directly from molecular geometry and pair-wise bonding structure. Trained on hydrogenic systems of modest size (H4H_4 and H6H_6) across tens of thousands of geometries, our model transfers to larger, unseen systems (H8H_8, H10H_{10} and H12H_{12}) without retraining -- demonstrating strong out-of-distribution generalization with respect to system size. When evaluating on structured and random configurations, and comparing against energies obtained with full classical optimization, our model reaches mean absolute energy errors O(102)\mathcal{O}(10^2) and O(10)\mathcal{O}(10) milli-Hartrees, respectively. Beyond energy estimation, the predicted orbitals serve as high-quality warm-start initializations that substantially reduce optimizer iterations to ground-state energy convergence. These results establish graph neural networks as an effective and scalable strategy for accelerating orbital optimization in hybrid quantum-classical workflows, directly reducing the classical pre-processing overhead that currently limits the practical deployment of variational quantum eigensolver on near-term quantum hardware.

Keywords

Cite

@article{arxiv.2605.04174,
  title  = {A Transferable Machine Learning Approach to Predict Optimized Orbitals for Electronic Structure Problems},
  author = {Lucas van der Horst and Maniraman Periyasamy and Abhishek Y. Dubey and Davide Bincoletto and Jakob S. Kottmann and Daniel D. Scherer},
  journal= {arXiv preprint arXiv:2605.04174},
  year   = {2026}
}

Comments

13 Pages, 4 Figures, 5 Tables

R2 v1 2026-07-01T12:51:38.408Z