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Can We Observe Nonperturbative Vacuum Shifts in Cavity QED?

Rocío Sáez‐Blázquez, Daniele De Bernardis, Johannes Feist, Peter Rabl

2023Physical Review Letters19 citationsDOIOpen Access PDF

Abstract

We address the fundamental question of whether or not it is possible to achieve conditions under which the coupling of a single dipole to a strongly confined electromagnetic vacuum can result in nonperturbative corrections to the dipole's ground state. To do so we consider two simplified, but otherwise rather generic cavity QED setups, which allow us to derive analytic expressions for the total ground-state energy and to distinguish explicitly between purely electrostatic and genuine vacuum-induced contributions. Importantly, this derivation takes the full electromagnetic spectrum into account while avoiding any ambiguities arising from an ad hoc mode truncation. Our findings show that while the effect of confinement per se is not enough to result in substantial vacuum-induced corrections, the presence of high-impedance modes, such as plasmons or engineered LC resonances, can drastically increase these effects. Therefore, we conclude that with appropriately designed experiments it is at least in principle possible to access a regime where light-matter interactions become nonperturbative.

Topics & Concepts

PhysicsQuantum electrodynamicsVacuum stateCoupling (piping)Ground stateDipoleQuantum mechanicsVacuum energyQED vacuumEngineeringMechanical engineeringStrong Light-Matter InteractionsQuantum Electrodynamics and Casimir EffectMechanical and Optical Resonators
Can We Observe Nonperturbative Vacuum Shifts in Cavity QED? | Litcius