Abstract
In this article we explore the dynamics of many-body atomic systems
symmetrically coupled to a single Lorentzian photonic cavity. Our study reveals
interesting dynamical characteristics including non-zero steady states,
superradiant decay, enhanced energy transfer and the ability to modulate
oscillations in the atomic system by tuning environmental degrees of freedom.
We also analyse a configuration consisting of a three-atom chain embedded in a
photonic cavity. Similarly, we find a strong enhancement of the energy transfer
rate between the two ends of the chain and identified specific initial
conditions that lead to significantly reduced dissipation between the two atoms
at the end of the chain. Another configuration of interest consists of two
symmetrical detuned reservoirs with respect to the atomic system. In the
single-atom case, we show that it is possible to enhance the decay rate of the
system by modulating its reservoir detuning, while in the many-atom case, this
results in dynamics akin to the on-resonant cavity. Finally, we examine the
validity of rotating wave approximation through a direct comparison against the
numerically exact hierarchical equations of motion approach. We find good
agreement in the weak coupling regime while in the intermediate coupling
regime, we identify qualitative similarities, but the rotating wave
approximation becomes less reliable. In the moderate coupling regime, we find
deviation of the steady states due to the formation of mixed photon atom
states.