Non-Hermitian Dynamics in Three-Level Systems: A Perturbative Approach for Time-Dependent Hamiltonians
Guixiang La, Yexin Li, Gongping Zheng

TL;DR
This paper explores how non-Hermitian interactions affect quantum transitions in three-level systems, revealing directional asymmetry and amplification under periodic driving.
Contribution
The study extends time-dependent perturbation theory to non-Hermitian three-level systems, revealing directional asymmetry and amplification in quantum transitions.
Findings
Quantum transitions in non-Hermitian systems show significant asymmetry and non-conservation depending on initial and final states.
Periodic driving amplifies the asymmetry in transition probabilities between forward and reverse processes.
Non-Hermiticity and resonance conditions enable selective enhancement or suppression of specific coupling channels.
Abstract
The conventional time-dependent perturbation theory in quantum mechanics is established within the framework of Hermitian Hamiltonians, applicable for describing quantum transitions and associated energy level responses in such systems. However, this theory has fundamental limitations when applied to non-Hermitian systems. Consequently, researchers have systematically extended time-dependent perturbation theory to non-Hermitian systems, establishing a corresponding mature framework. Building on this foundation, this study extends the theory to investigate the transition dynamics induced by non-Hermitian interactions in non-Hermitian Hamiltonian systems. We employ a biorthogonal basis representation for a three-level non-Hermitian system. This work investigates a system comprising an unperturbed static non-Hermitian Hamiltonian and a periodically driven time-dependent perturbation…
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Taxonomy
TopicsQuantum Mechanics and Non-Hermitian Physics · Quantum chaos and dynamical systems · Advanced Physical and Chemical Molecular Interactions
