Triple Threshold Transitions and Strong Polariton Interaction in 2D Layered Metal-Organic Framework Microplates.

Room-temperature interaction between light-matter hybrid particles such as exciton-polaritons under extremely low-pump plays a crucial role in future coherent quantum light sources. However, the practical and scalable realization of coherent quantum light sources operating under low-pump remains a challenge because of the insufficient polariton interaction strength. Here, at room temperature, a very large polariton interaction strength is demonstrated, g ≈ 128 ± 21 µeV µm 2 realized in a 2D nanolayered metal-organic framework (MOF). As a result, a polariton lasing at an extremely low pump fluence of P 1  ≈ 0.01 ± 0.0015 µJ cm -2 (first threshold) is observed. Interestingly, as pump fluencies increase to P 2  ≈ 0.031 ± 0.003 µJ cm -2 (second threshold), a spontaneous transition to a polariton breakdown region occurrs, which has not been reported before. Finally, an ordinary photon lasing occurrs at P 3  ≈ 0.11 ± 0.077 µJ cm -2 (third threshold), or above. These experiments and the theoretical model reveal new insights into the transition mechanisms characterized by three distinct optical regions. This work introduces MOF as a new type of quantum material, with naturally formed polariton cavities, that is a cost-effective and scalable solution to build microscale coherent quantum light sources and polaritonic devices.