Gain enhanced metal nanoshells: below and above the emission threshold

Nanotechnology has revolutionized our ability to control matter at the nanoscale, with metallic nanostructures offering remarkable versatility. Metallic nanoparticles (MNs) find compelling applications when metal losses are balanced by optical gain elements, including visible-frequency metamaterial cloaking and sensitive bio-molecular sensors. Prior studies of the electromagnetic response of these nano-systems have focused on single spherical MNs within infinite gain media, facing non-uniformity challenges beyond emission thresholds. To overcome this issue, we propose transitioning to spherical nanoshells incorporating gain elements, facilitating field homogeneity and offering a comprehensive spectral description using a hybrid quasi-static model. This system enables us to describe the electromagnetic behavior of the MN below as well as above the emission threshold. Interestingly, we found that the steady-state emission of a gain enhanced nanoshell is not the single line emission predicted by other authors, but instead it involves a range of frequencies whose span is governed by physical and morphological parameters that can be chosen at the stage of synthesis to design an optimal emitter.