A. Kudlis, I. A. Aleksandrov, K. Varga, I. A. Shelykh, V. Shahnazaryan
Published 2024-06-07Version 1
Magnetic field is a powerful tool for the manipulation of material's electronic and optical properties. In the domain of transition metal dichalcogenide monolayers, it allows one to unveil the spin, valley, and orbital properties of many-body excitonic complexes. Here we study theoretically the impact of normal-to-plane magnetic field on trions and trion-polaritons. We demonstrate that spin and orbital effects of a magnetic field give comparable contributions to the trion energies. Moreover, as magnetic field redistributes the free electron gas between two valleys in the conductance band, the trion-photon coupling becomes polarization and valley dependent. This results in an effective giant Zeeman splitting of trion-polaritons, in-line with the recent experimental observations.
Landau diamagnetism of the free electron gas as a Fermi surface effect
Intrinsic exciton states mixing and non-linear optical properties in transition metal dichalcogenide monolayers
Experimental observation of topological exciton-polaritons in transition metal dichalcogenide monolayers
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