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Time-domain modeling of interband transitions in plasmonic systems

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arxiv 2209.04263 v1 pith:UARKUGH6 submitted 2022-09-09 physics.optics physics.comp-ph

Time-domain modeling of interband transitions in plasmonic systems

classification physics.optics physics.comp-ph
keywords approachinterbandplasmonictransitionsequationsmaterialsparameterstime-domain
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Efficient modeling of dispersive materials via time-domain simulations of the Maxwell equations relies on the technique of auxiliary differential equations. In this approach, a material's frequency-dependent permittivity is represented via a sum of rational functions, e.g. Lorentz-poles, and the associated free parameters are determined by fitting to experimental data. In the present work, we present a modified approach for plasmonic materials that requires considerably fewer fit parameters than traditional approaches. Specifically, we consider the underlying microscopic theory and, in the frequency domain, separate the hydrodynamic contributions of the quasi-free electrons in partially filled bands from the interband transitions. As an illustration, we apply our approach to gold and demonstrate how to treat the interband transitions within the effective model via connecting to the underlying electronic bandstructure, thereby assigning physical meaning to the remaining fit parameters. Finally, we show how to utilize this approach within the technique of auxiliary differential equations. Our approach can be extended to other plasmonic materials and leads to efficient time-domain simulations of plasmonic structures for frequency ranges where interband transitions have to be considered.

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