Non-Hermitian Linear Electro-Optic Effect Through Interactions of Free and Bound Charges

Abstract: In recent years, there has been significant interest in non-Hermitian phenomena, particularly optical gain, stemming from electro-optic effects. Typically, these effects are attributed to nonlinear interactions arising from the ``anomalous velocity" of Bloch electrons. Here, we introduce a novel mechanism for achieving optical gain through nonlinear interactions between free and bound electrons. We propose a semiclassical phenomenological microscopic model that encompasses a broad spectrum of nonlinear interactions, consistent with passivity and with the principles of microscopic reversibility. Our analysis shows that under non-equilibrium conditions and within low-symmetry systems, the linearized electromagnetic response can display both nonreciprocal and gain properties. We examine the stability of these electrically-biased systems and illustrate their potential applications, including the development of optical isolators and traveling wave amplifiers.