English

Interband Plasmonics with p-block Elements

Optics 2016-01-08 v1

Abstract

We investigate the origin of the near-ultraviolet visible plasmonic properties of three elemental materials from the p-block: Bi, Sb and Ga, with the aim to achieve and exploit unconventional plasmonic effects beyond those provided by noble metals. At such aim, we review and analyze a broad range of optically-determined dielectric functions e of these elemental materials available in the literature, covering a wide photon energy range (from 0.03 to 24 eV). It is shown that the contribution of Drude-like carriers to e1 (real part of e) in the near-ultraviolet visible is negligible for Bi and Sb and moderate for Ga. In contrast, the interband transitions of these elemental materials show a high oscillator strength that yields a strong negative contribution to e1 in the near-ultraviolet visible. Therefore in these materials interband transitions are not a mere damping channel detrimental to plasmonic properties. Remarkably, these interband transitions induce fully (partially) the localized surface plasmon-like resonances taking place in Bi and Sb (Ga) nanostructures in the near-ultraviolet visible. Plasmonic properties achieved through interband transitions, without Drude-like carrier excitation, are very attractive phenomena because they may give rise to a rich and broad class of nanostructures and metamaterials in which plasmonic effects will be tunable through the tailoring of band structure and by the occupancy of electronic states.

Keywords

Cite

@article{arxiv.1601.01606,
  title  = {Interband Plasmonics with p-block Elements},
  author = {Johann Toudert and Rosalia Serna},
  journal= {arXiv preprint arXiv:1601.01606},
  year   = {2016}
}
R2 v1 2026-06-22T12:24:53.074Z