Nonreciprocal spontaneous parametric process

Abstract

Mediated by the interaction with quantum vacuum fields, a laser field propagating in a nonlinear optical medium can generate new light fields via spontaneous parametric process. Such process is inherent independent of the propagation direction of light and reciprocal thus far, due to the direction-independent field-vacuum interaction. In this work, we experimentally demonstrate a nonreciprocal spontaneous parametric four-wave mixing process in sodium atomic vapors with dispersive nonlinearity and further broadband optical isolation by unidirectionally coupling the probe field to an auxiliary quantum vacuum field in another four-wave mixing process. Thanks to the broad bandwidth of the spontaneous parametric process, in combination with the Doppler and power-induced broadening of atomic energy levels, we achieve optical isolation with a bandwidth larger than 100 GHz for isolation ratio >25 dB. Considering that both spontaneous parametric processes and wave mixing in nonlinear medium have been realized in diverse on-chip photonic platforms, our work paves the way for integrated broadband optical isolations and thus can boost scalability and function of photonic chips.