Plasmonic Dielectric Response of Finite Temperature Electron Gas

Abstract: In this research we report the dielectric response of a finite temperature electron gas, electrostatically interacting with both external and self-induced plasmonic fields, in the well-known random phase approximation. The generalized energy dispersion relation which incorporates the plasmonic band structure is used to calculate the Lindhard dielectric response of homogenous electron gas from which many important physical functionals, such as the structure factor, loss function, screening potential, optical re… Show more

“…While these theories can be reconciled when corrections are taken into account [69], the fundamental theory of plasmonics must go well beyond these correction and approximations. In an unpublished resent research the Lindhard theory is used with a more general dual length-scale energy dispersion which includes both single-electron as well as collective behavior [70]. It is seen that, the obtained results of such adjustment deviates substantially from prediction of both conventional quantum hydrodynamic and the Lindhard theory.…”

Quantum edge plasmon excitations and electron spill-out effect

“…While these theories can be reconciled when corrections are taken into account [69], the fundamental theory of plasmonics must go well beyond these correction and approximations. In an unpublished resent research the Lindhard theory is used with a more general dual length-scale energy dispersion which includes both single-electron as well as collective behavior [70]. It is seen that, the obtained results of such adjustment deviates substantially from prediction of both conventional quantum hydrodynamic and the Lindhard theory.…”

Quantum edge plasmon excitations and electron spill-out effect