The light-matter correlation energy functional of the cavity-coupled two-dimensional electron gas via quantum Monte Carlo simulations
- URL: http://arxiv.org/abs/2412.19222v1
- Date: Thu, 26 Dec 2024 14:03:03 GMT
- Title: The light-matter correlation energy functional of the cavity-coupled two-dimensional electron gas via quantum Monte Carlo simulations
- Authors: Lukas Weber, Miguel A. Morales, Johannes Flick, Shiwei Zhang, Angel Rubio,
- Abstract summary: We show that a modified version of weak-coupling theory is remarkably accurate for a large parameter region.
Results provide a numerical foundation for the development of the QED density functional theory.
- Score: 10.311466600238516
- License:
- Abstract: We perform extensive simulations of the two-dimensional cavity-coupled electron gas in a modulating potential as a minimal model for cavity quantum materials. These simulations are enabled by a newly developed quantum-electrodynamical (QED) auxiliary-field quantum Monte Carlo method. We present a procedure to greatly reduce finite-size effects in such calculations. Based on our results, we show that a modified version of weak-coupling perturbation theory is remarkably accurate for a large parameter region. We further provide a simple parameterization of the light-matter correlation energy as a functional of the cavity parameters and the electronic density. These results provide a numerical foundation for the development of the QED density functional theory, which was previously reliant on analytical approximations, to allow quantitative modeling of a wide range of systems with light-matter coupling.
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