Resonance interaction of two entangled atoms accelerating between two mirrors

TL;DR

This paper investigates how the resonance interaction between two entangled atoms, accelerating between two mirrors, can be manipulated by adjusting parameters like acceleration, distance, and position, revealing controllable quantum effects.

Contribution

It introduces a detailed analysis of resonance energy shifts and relaxation rates for entangled atoms in noninertial motion near boundaries, highlighting controllable quantum interactions.

Findings

Resonance energy shift depends on acceleration and boundary conditions.

Relaxation rate can be tuned via atomic position and interatomic distance.

Quantum interaction effects are controllable through system parameters.

Abstract

We study the resonance interaction between two entangled identical atoms coupled to a quantized scalar field vacuum, and accelerating between two mirrors. We show how radiative processes of the two-atom entangled state can be manipulated by the atomic configuration undergoing noninertial motion. Incorporating the Heisenberg picture with symmetric operator ordering, the vacuum fluctuation and the self-reaction contributions are distinguished. We evaluate the resonance energy shift and the relaxation rate of energy of the two atom system from the self-reaction contribution in the Heisenberg equation of motion. We investigate the variation of these two quantities with relevant parameters such as atomic acceleration, interatomic distance and position with respect to the boundaries. We show that both the energy level shift and the relaxation rate can be controlled by tuning the above parameters.