Strong coupling between molecules and confined light modes of optical cavities to form
polaritons can alter photochemistry, but the origin of this effect remains largely unknown …

Exciton transport can be enhanced in the strong coupling regime where excitons hybridize
with confined light modes to form polaritons. Because polaritons have group velocity, their …

Experiments have demonstrated that the strong light-matter coupling in polaritonic
microcavities significantly enhances transport. Motivated by these experiments, we have …

We present a comprehensive study of the exciton wave packet evolution in disordered
lossless polaritonic wires. Our simulations reveal signatures of ballistic, diffusive, and …

Transport of excitons in organic materials can be enhanced through polariton formation
when the interaction strength between these excitons and the confined light modes of an …

Excitation energy transport can be significantly enhanced by strong light–matter interactions.
In the present work, we explore intriguing features of coherent transient exciton wave packet …

The vacuum Rabi splitting (VRS) in molecular polaritons stands as a fundamental measure
of collective light–matter coupling. Despite its significance, the impact of molecular disorder …

Chemical reactions and energy transport phenomena have been experimentally reported to
be significantly affected by strong light–matter interactions and vibrational polariton …

We apply the Kubo-Anderson stochastic theory of molecular spectral line shapes to the case
of polaritons formed in the collective strong-coupling regime. We investigate both the fast …

We present a powerful formalism (d-CUT-E) to simulate the ultrafast quantum dynamics of
molecular polaritons in the collective strong coupling regime, where a disordered ensemble …