Quasi-analytical solutions of wide-angle and broadband insulator-metal grating-metal metamaterial absorber in visible to near-infrared bands

TL;DR

This paper introduces a quasi-analytical model for wide-angle, broadband insulator-metal grating-metal metamaterial absorbers in the visible to near-infrared spectrum, demonstrating high absorption efficiency and angle insensitivity.

Contribution

It develops a novel quasi-analytical solution for IMM-absorbers considering finite metal dielectric constants, validated by FDTD simulations, and explores material and structural optimizations.

Findings

Best tungsten-based absorber achieves 96.2% average absorbance.

Absorbers maintain over 90% absorbance for incident angles up to 66 degrees.

Broadband absorption is due to insulator-metal and slit waveguide resonances.

Abstract

A metamaterial absorber converts solar radiation into heat for applications in thermoelectric generators and solar thermophotovoltaics. A metamaterial absorber typically consists of metallic parts separated by an insulator layer which does not allow the total heat extraction via direct heat conduction. Here, we propose wide-angle and broadband metamaterial absorber comprising an insulator layer, metal grating, and metal back plane (IMM) that allows the total heat extraction via direct heat conduction. We have formulated the quasi-analytical solution (QANS) of the IMM-absorber by applying the coupled-mode analysis with new technique for taking finite dielectric constant of a metal into account. The QANS are consistent with finite difference time domain (FDTD) simulation. We fine that the IMM-absorbers made by tungsten and silver metals give the best and worse average absorbance over the wavelength range 400-1,200 nm, respectively. The best IMM-absorber shows the optimized average absorbance 96.2%. The broadband absorption results from the excitations of insulator-metal waveguide resonance and slit waveguide resonance that are insensitive to incident angles. The averaged absorbance is above 90.0% for the incident angles 0-66 degree. The IMM-absorber performance may be enhanced by using metal rod array with engineered supperlattice.