English

Phase Space Electronic Structure Theory: From Diatomic Lambda-Doubling to Macroscopic Einstein-de Haas

Chemical Physics 2026-01-26 v2 Atomic Physics Quantum Physics

Abstract

Λ\Lambda-doubling of diatomic molecules is a subtle microscopic phenomenon that has long attracted the attention of experimental groups, insofar as rotation of molecular nuclei\textit{nuclei} induces small energetic changes in the (degenerate) electronic\textit{electronic} state. A direct description of such a phenomenon clearly requires going beyond the Born-Oppenheimer approximation. Here we show that a phase space theory previously developed to capture electronic momentum and model vibrational circular dichroism -- and which we have postulated should also describe the Einstein-de Haas effect, a macroscopic manifestation of angular momentum conservation -- is also able to recover the Λ\Lambda-doubling energy splitting (or Λ\Lambda-splitting) of the NO molecule nearly quantitatively. The key observation is that, by parameterizing the electronic Hamiltonian in terms of both nuclear position (X\mathbf{X}) and nuclear momentum (P\mathbf{P}), a phase space method yields potential energy surfaces that explicitly include the electron-rotation coupling and correctly conserve angular momentum (which we show is essential to capture Λ\Lambda-doubling). The data presented in this manuscript offers another small glimpse into the rich physics that one can learn from investigating phase space potential energy surfaces EPS(X,P)E_{PS}(\mathbf{X},\mathbf{P}) as a function of both nuclear position and momentum, all at a computational cost comparable to standard Born-Oppenheimer electronic structure calculations.

Keywords

Cite

@article{arxiv.2512.13448,
  title  = {Phase Space Electronic Structure Theory: From Diatomic Lambda-Doubling to Macroscopic Einstein-de Haas},
  author = {Linqing Peng and Tian Qiu and Nadine Bradbury and Xuezhi Bian and Mansi Bhati and Robert Littlejohn and Nathanael M. Kidwell and Joseph E. Subotnik},
  journal= {arXiv preprint arXiv:2512.13448},
  year   = {2026}
}
R2 v1 2026-07-01T08:25:29.834Z