Research efforts of cavity quantum electrodynamics have focused on the manipulation of matter hybridized with photons under the strong coupling regime1(link is external),2(link is external),3(link is external). This has led to striking discoveries including polariton condensation2(link is external) and single-photon nonlinearity3(link is external), where the phonon scattering plays a critical role1(link is external),2(link is external),3(link is external),4(link is external),5(link is external),6(link is external),7(link is external),8(link is external),9(link is external). However, resolving the phonon scattering remains challenging for its non-radiative complexity. Here we demonstrate nonlinear phonon scattering in monolayer MoS2 that is strongly coupled to a plasmonic cavity mode. By hybridizing excitons and cavity photons, the phonon scattering is equipped with valley degree of freedom and boosted with superlinear enhancement to a stimulated regime, as revealed by Raman spectroscopy and our theoretical model. The valley polarization is drastically enhanced and sustained throughout the stimulated regime, suggesting a coherent scattering process enabled by the strong coupling. Our findings clarify the feasibility of valley–cavity-based systems for lighting, imaging, optical information processing and manipulating quantum correlations in cavity quantum electrodynamics.
Abstract:
Publication date:
April 12, 2021
Publication type:
Journal Article