Beyond the Drude model: surface and non-local effects in near-field radiative heat transfer and the Casimir puzzle
Abstract
We study the charge and current response functions P and in a semi-infinite metal block using the electron surface Green's functions. The surface electrons behave similarly to a two-dimensional Fermi gas but are strongly damped due to coupling to the bulk. This substantially reduces the region of validity of the Drude model for P, which requires the frequency ω ( vF q, 1/τ), here vF is the Fermi velocity, q is the wavevector and τ is an effective relaxation time. As a consequence, for typical metal in near-field heat transfer, the Coulomb interaction goes as 1/d4 with the distance of the vacuum gap instead of the well-known 1/d2 of Drude model result. The current response is shown to be highly anisotropic. The Drude model describes well the transverse directions parallel to the surface but is very different in the normal direction up to about 100 lattice sites away from the surface. These ideas and the residue diamagnetic effect of a nonzero on the surface at zero frequency still cannot resolve the Casimir puzzle.
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