English

Spin parameter optimization for spin-polarized extended tight-binding methods

Chemical Physics 2024-05-10 v1

Abstract

We present an optimization strategy for atom-specific spin-polarization constants within the spin-polarized GFN2-xTB framework, aiming to enhance the accuracy of molecular simulations. We compare a sequential and global optimization of spin parameters for hydrogen, carbon, nitrogen, oxygen, and fluorine. Sensitivity analysis using Sobol indices guides the identification of the most influential parameters for a given reference dataset, allowing for a nuanced understanding of their impact on diverse molecular properties. In the case of the W4-11 dataset, substantial error reduction was achieved, demonstrating the potential of the optimization. Transferability of the optimized spin-polarization constants over different properties, however, is limited, as we demonstrate by applying the optimized parameters on a set of singlet-triplet gaps in carbenes. Further studies on ionization potentials and electron affinities highlight some inherent limitations of current extended tight-binding methods that can not be resolved by simple parameter optimization. We conclude that the significantly improved accuracy strongly encourages the present re-optimization of the spin-polarization constants, whereas the limited transferability motivates a property-specific optimization strategy.

Keywords

Cite

@article{arxiv.2405.05761,
  title  = {Spin parameter optimization for spin-polarized extended tight-binding methods},
  author = {Siyavash Moradi and Rebecca Tomann and Josie Hendrix and Martin Head-Gordon and Christopher J. Stein},
  journal= {arXiv preprint arXiv:2405.05761},
  year   = {2024}
}
R2 v1 2026-06-28T16:22:07.889Z