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Fresnel coefficients and Fabry-Perot formula for spatially dispersive metallic layers

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 Added by Antoine Moreau
 Publication date 2017
  fields Physics
and research's language is English




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The repulsion between free electrons inside a metal makes its optical response spatially dispersive, so that it is not described by Drudes model but by a hydrodynamic model. We give here fully analytic results for a metallic slab in this framework, thanks to a two-modes cavity formalism leading to a Fabry-Perot formula, and show that a simplification can be made that preserves the accuracy of the results while allowing much simpler analytic expressions. For metallic layers thicker than 2.7 nm modified Fresnel coefficients can actually be used to accurately predict the response of any multilayer with spatially dispersive metals (for reflection, transmission or the guided modes). Finally, this explains why adding a small dielectric layer[Y. Luo et al., Phys. Rev. Lett. 111, 093901 (2013)] allows to reproduce the effects of nonlocality in many cases, and especially for multilayers.



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