Wave-packet dynamics in a non-Hermitian exciton-polariton system

We theoretically investigate the dynamics of wave packets in a generic, non-Hermitian, optically anisotropic exciton-polariton system that exhibits degeneracies of its complex-valued eigenenergies in the form of pairs of exceptional points in momentum space. We observe the self-acceleration and reshaping of the wave packets governed by their eigenenergies. We further find that the exciton-polariton wave packets tend to evolve into the eigenstate with the smaller decay rate, then propagate towards the minima of the decay rates in momentum space, resulting in directional transport in real space. We also describe the formation of pseudospin topological defects on the imaginary Fermi arc, where the decay rates of the two eigenstates coincide in momentum space. These effects of non-Hermiticity on the dynamics of exciton polaritons can be observed experimentally in a microcavity with optically anisotropic cavity spacer or exciton-hosting materials. This rich non-Hermitian dynamics can also be observed in other two-dimensional, two-band systems with similar complex band structures such as purely photonic planar microcavities, liquid crystal cavities, and non-Hermitian photonic lattices.

Automated summary

We theoretically investigate the dynamics of wave packets in a non-Hermitian, optically anisotropic exciton-polariton system and observe their self-acceleration and reshaping governed by their eigenenergies. The exciton-polariton wave packets tend to evolve into states with smaller decay rates, resulting in directional transport in real space. Pseudospin topological defects are also found on the imaginary Fermi arc. These dynamics can be observed experimentally in microcavities and other two-dimensional systems.