Effect of quantum confinement on the blueshift of optically-trapped exciton polaritons below the condensation threshold

Exciton polaritons offer a unique nonlinear platform for studies of collective macroscopic quantum phenomena in a solid state. Recently, shaping of polariton flow and polariton confinement via nonresonant optical pumping has gained considerable attention due to experimentally convenient flexibility and control of the optically-induced potentials. In this work, we investigate the origins of the large energy shifts (blueshifts) of exciton polaritons confined in optically-induced round traps observed in the regime where the density of exciton polaritons is very low. We present evidence of the quantum confinement effect, namely a significant blueshift of the exciton-polariton energy due to reshaping of the optically-induced potential with the laser pump power. Our work therefore demonstrates one possible mechanism for the energy blueshift observed well below the exciton-polariton condensation threshold, and calls for revision of the recent interpretation of this effect as an evidence of strong exciton-polaritons interactions [Nature Phys. 13, 870 (2017)].