Enhanced polariton interactions in suspended WS2 monolayer microcavity

Transition-metal dichalcogenides monolayers exhibit strong exciton resonances that enable intense light-matter interactions at room temperature (RT). However, the sensitivity of these materials to the surrounding environment and their intense interactions with the sustaining substrate result in the enhancement of excitonic losses through scattering, dissociation and defects formation, hindering their full potential for the excitation of optical nonlinearities in exciton-polariton platforms. From this point of view, the use of suspended monolayers holds the potential to completely eliminate substrate-induced losses, offering unique advantages for the investigation and exploitation of intrinsic electronic, mechanical, and optical properties of 2D materials based polaritonic systems, without any influence of proximity effects of all sort. In this work, we report a novel fabrication approach enabling the realization of a planar {\lambda}/2 microcavity filled with a suspended WS2 monolayer in its centre. In such a system, we experimentally demonstrate a 2-fold enhancement of the strong coupling at RT, due to reduced overall losses as compared to similar systems based on dielectric-filled microcavities. Moreover, as a result of minimized losses, spin-dependent polaritonic interactions in our platform are significantly amplified, leading to achievement of a record exciton interaction constant approaching the theoretically predicted value at RT, without making use of theoretical hypothesis on the effective polariton densities. This approach holds promises for pushing 2D materials-based polaritonic systems to their intrinsic limits, paving the way for the realization of novel polaritonic devices with superior performance.