Surface-response functions obtained from equilibrium electron-density profiles
Abstract
Surface-response functions are one of the most promising routes for bridging the gap between fully quantum-mechanical calculations and phenomenological models in quantum nanoplasmonics. Within all the currently available recipes for obtaining such response functions, \emph{ab initio} calculations remain one of the most predominant, wherein the surface-response function are retrieved via the metal's non-equilibrium response to an external perturbation. Here, we present a complementary approach where one of the most appealing surface-response functions, namely the Feibelman -parameters, yield a finite contribution even in the case where they are calculated directly from the equilibrium properties described under the local-response approximation (LRA), but with a spatially varying equilibrium electron density. Using model calculations that mimic both spill-in and spill-out of the equilibrium electron density, we show that the obtained -parameters are in qualitative agreement with more elaborate, but also more computationally demanding, \emph{ab initio} methods. The analytical work presented here illustrates how microscopic surface-response functions can emerge out of entirely local electrodynamic considerations.
Cite
@article{arxiv.2103.00162,
title = {Surface-response functions obtained from equilibrium electron-density profiles},
author = {N. Asger Mortensen and P. A. D. Gonçalves and Fedor A. Shuklin and Joel D. Cox and Christos Tserkezis and Masakazu Ichikawa and Christian Wolff},
journal= {arXiv preprint arXiv:2103.00162},
year = {2021}
}
Comments
Supplementary material is available upon request to authors