Effect of atom-oscillator interaction on the aging transition in coupled oscillators

TL;DR

This paper investigates how coherent atom-oscillator interactions influence aging transitions in coupled oscillators, revealing that such interactions can lower the threshold for aging, with implications for quantum control.

Contribution

It introduces a novel method to modulate aging transitions via atom-oscillator coherent coupling, expanding control strategies in quantum oscillator systems.

Findings

Atom-oscillator coherence reduces the inactive oscillator ratio needed for aging.

Decay rate and coupling strength jointly influence the aging transition point.

Analytical results apply to both classical and quantum oscillators.

Abstract

Oscillators are often employed as a model of radiation fields, which may couple to an atom and play an important role for creating and manipulating nonclassical states in quantum metrology, quantum simulation, and quantum information. Aging transitions in coupled oscillators have been studied extensively in both the classical and quantum contexts. It is well known that the onset of aging transitions can be modulated by the dissipative coupling between oscillators. In this study, we propose an alternative way to modulate the aging transition through coherent couplings between a two-level atom and the oscillators. Our findings reveal that, compared to atom-free systems in both classical and quantum regimes, the atom-oscillator coherent interaction reduces the inactive-to-total oscillator ratio required for aging transitions. Analytical results of the transition for both the classical oscillators and quantum oscillators suggest that the decay rate of the atom and the atom-oscillator coupling strength jointly change the aging transition point. The physics behind the observation is also elucidated in this article. Our research introduces a readily implementable strategy for manipulating aging transitions in more intricate systems, thereby advancing the control and understanding of these critical transitions in quantum technologies.