Theory for the stationary polariton response in the presence of vibrations
Abstract
We construct a model describing the response of a hybrid system where the electromagnetic field—in particular, surface plasmon polaritons—couples strongly with electronic excitations of atoms or molecules. Our approach is based on the inputoutput theory of quantum optics, and in particular it takes into account the thermal and quantum vibrations of the molecules. The latter is described within the P (E ) theory analogous to that used in the theory of dynamical Coulomb blockade. As a result, we are able to include the effect of the molecular Stokes shift on the strongly coupled response of the system. Our model then accounts for the asymmetric emission from upper and lower polariton modes. It also allows for an accurate description of the partial decoherence of the light emission from the strongly coupled system. Our results can be readily used to connect the response of the hybrid modes to the emission and fluorescence properties of the individual molecules, and thus are relevant in understanding any utilization of such systems, such as coherent light harvesting.
 Publication:

Physical Review B
 Pub Date:
 December 2019
 DOI:
 10.1103/PhysRevB.100.245426
 arXiv:
 arXiv:1905.01212
 Bibcode:
 2019PhRvB.100x5426K
 Keywords:

 Quantum Physics;
 Condensed Matter  Mesoscale and Nanoscale Physics
 EPrint:
 13 pages, 6 figures