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A unified theory for perfect absorption in ultra-thin absorptive films with constant tangential electric or magnetic fields

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arxiv 1405.6475 v2 pith:KZENXS54 submitted 2014-05-26 physics.optics

A unified theory for perfect absorption in ultra-thin absorptive films with constant tangential electric or magnetic fields

classification physics.optics
keywords absorptionultra-thinfilmperfectalmostconstantelectricfilms
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The maximal absorption rate of ultra-thin films is 50% under the condition that the tangential electric (or magnetic) field is almost constant across the film in symmetrical environment. However, with certain reflectors, the absorption rate can be greatly increased, to even perfect absorption (100%). In this work, we explicitly derive the general conditions of the ultra-thin absorptive film parameters to achieve perfect absorption with general types of reflectors under the condition that the tangential electric (or magnetic) field is almost constant across the film. We find that the parameters of the film can be classified into three groups, exhibiting: 1) a large permittivity (permeability), 2) a near-zero permeability (permittivity), or 3) a suitable combination of the permittivity and the permeability, respectively. Interestingly, the latter two cases demonstrate extraordinary absorption in ultra-thin films with almost vanishing losses. Our work serves as a guide for designing ultra-thin perfect absorbers with general types of reflectors.

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