Simple structured ultranarrow‐band metamaterial perfect absorber with dielectric‐dielectric‐metal configuration

A simple structured ultranarrow‐band metamaterial perfect absorber (MPA) with dielectric‐dielectric‐metal configuration is studied both theoretically and experimentally. By optimizing the dielectric connectivity layer and metal substrate, the optimized simple structured ultranarrow‐band MPA is obtained. Theoretical simulation results show that the MPA exhibits single ultranarrow absorption peak at normal incidence and double ultranarrow absorption peaks at oblique incidence. The heat power density distributions of the optimized MPA are also calculated to depict the absorption mechanism. At last, we fabricate a MPA sample and measure its absorption spectra to make a further comparison. The experimental data are consistent with the theoretical ones. This novel method might be helpful to reduce the manufacture difficulty and cost of the ultranarrow‐band MPAs, and also to promote the development of applications of the ultranarrow‐band MPAs.

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