English

Quantum Wigner molecules in moir\'{e} materials

Strongly Correlated Electrons 2023-10-02 v2 Mesoscale and Nanoscale Physics

Abstract

The few-body problem (with N6N \leq 6 fermionic charge carriers) in isolated moir\'{e} quantum dots (MQDs) in transition metal dichalcogenide (TMD) bilayer materials with integer fillings, ν2\nu \geq 2, is investigated by employing large-scale full configuration interaction (FCI, also termed exact-diagonalization) computations, and by performing a comparative analysis of the ensuing first-order (charge densities, CDs) and second-order (conditional probability distributions, CPDs) correlation functions. With parameters representative of bilayer experimental TMD setups, our investigations reveal the determining role of the strong inter-particle Coulombic repulsion in bringing about Wigner molecularization, which is associated with many-body physics beyond both that described by the Aufbau principle of natural atoms, as well as by the widely used Hubbard model for strongly-interacting condensed-matter systems. In particular, for weak and moderate trilobal crystal-field deformations of the MQDs, the imperative employment of the CPDs brings to light the geometrical polygonal-ring configurations underlying the Wigner molecules (WMs) that remain hidden at the level of a charge-density analysis, apart from the case of N=3N=3 when a pinned WM emerges in the charge density due to the coincidence of the C3C_3 symmetries associated with both the intrinsic geometry of the N=3N=3 WM and the TMD trilobal crystal-field of the confining pocket potential. The FCI numerically exact-diagonalization results provide critical benchmarks for assessing and guiding the development of future computational methodologies of interacting strongly-correlated fermions in isolated MQDs and their superlattices in TMD materials.

Keywords

Cite

@article{arxiv.2305.02516,
  title  = {Quantum Wigner molecules in moir\'{e} materials},
  author = {Constantine Yannouleas and Uzi Landman},
  journal= {arXiv preprint arXiv:2305.02516},
  year   = {2023}
}

Comments

Published version (Editors' Suggestion). 11 pages. 7 color figures. For related papers, see https://sites.gatech.edu/cyannouleas/

R2 v1 2026-06-28T10:25:12.744Z