Bistable optical response of nanoparticle heterodimer: Mechanism, phase diagram, and switching time

Abstract

We conduct a theoretical study of the bistable optical response of a nanoparticle heterodimer comprised of a closely spaced semiconductor quantum dot and metal nanoparticle. The bistable nature of the response results from the interplay between the quantum dot's optical nonlinearity and its self-action (feedback) originating from the presence of the metal nanoparticle. We show that the feedback is governed by a complex valued coupling parameter G. Both the real and imaginary parts of G (GR and GI) play an important role in the occurrence of bistability, which is manifested in an S-shaped dependence of the quantum dot excited state population on the intensity of the external field, and hysteresis of the population. From our calculations, we find that at GR = 0, the critical value for bistability to occur is GI = 8, whereas at GI = 0, the critical value of GR = 4, where is the polarization dephasing rate. Thus, there exist two different (limiting) mechanisms of bistability, depending on whether GR is much larger or much smaller than GI. We also calculate the bistability phase diagram within the system's parameter space: spanned by GR, GI and , the latter being the detuning between the driving frequency and the transition frequency of the quantum dot. Additionally, switching times from the lower stable branch to the upper one (and vise versa) are calculated as a function of the intensity of the driving field. We show that the conditions for bistability to occur can be realized, for example, for a heterodimer comprised of a closely spaced CdSe (or CdSe/ZnSe) quantum dot and a gold nanosphere.