Absorption and scattering in perfect thermal radiation absorber-emitter metasurfaces

Detailed spectral analysis of radiation absorption and scattering behaviors of metasurfaces was carried out via finite-difference time-domain (FDTD) photonic simulations. It revealed that, for typical metal-insulator-metal (MIM) nanodisc metasurfaces, absorbance and scattering cross-sections exhibit a ratio of sigma(abs)/sigma(sca) = 1 at the absorption peak spectral position. This relationship was likewise found to limit the attainable photo-thermal conversion efficiency in experimental and application contexts. By increasing the absorption due to optical materials, such as Cr metal nano-films typically used as an adhesion layer, it is possible to control the total absorption efficiency eta = sigma(abs)/sigma(sca) and to make it the dominant extinction mechanism. This guided the design of MIM metasurfaces tailored for near-perfect-absorption and emission of thermal radiation. We present the fabrication as well as the numerical and experimental spectral characterisation of such optical surfaces. (c) 2022 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement

Automated summary

This study conducted a detailed spectral analysis of the radiation absorption and scattering behaviors of metasurfaces through photonic simulations. It was found that the absorbance and scattering cross-sections exhibit a ratio of 1 at the absorption peak spectral position. By increasing the absorption through optical materials, the total absorption efficiency can be controlled, leading to near-perfect absorption and emission of thermal radiation.