Thin flexible multi-octave metamaterial absorber for millimetre wavelengths

TL;DR

This paper introduces a novel, ultra-wideband, thin flexible metamaterial absorber for millimetre wavelengths, achieving over 99% absorption across 80-400 GHz with stable performance at various angles, suitable for advanced astronomical instruments.

Contribution

The paper presents the first successful design and fabrication of a low-profile, ultra-wideband metamaterial absorber operating from 80-400 GHz with high absorption efficiency and angular stability.

Findings

Achieved >99% absorption across 80-400 GHz

Demonstrated stable performance at ±10° incidence

Validated design with experimental and simulation agreement

Abstract

Development of novel radiation-absorbent materials and devices for millimetre and submillimetre astronomy instruments is a research area of high interest, and with substantial engineering challenges. Alongside low-profile structure and ultra-wideband performance in a wide range of angles of incidence, advanced absorbers in CMB instruments are aimed at reducing optical systematics, notably instrument polarisation, far beyond previous specifications. This paper presents an innovative design of flat thin flexible absorber operating in a wide frequency range of 80-400 GHz. The structure comprises a combination of sub-wavelength metal-mesh capacitive and inductive grids and dielectric layers, making use of the magnetic mirror concept for large bandwidth. The overall stack thickness is a quarter of the longest operating wavelength and is close to the theoretical limit stipulated by Rozanov criterion. The test device is designed to operate at 22.5deg. incidence. The iterative numerical-experimental design procedure of the new absorber is discussed in detail, as well as the practical challenges of its manufacture. A well-established mesh-filter fabrication process has been successfully employed for prototype fabrication, which ensures cryogenic operation of the hot-pressed quasi-optical devices. The final prototype, extensively tested in quasi-optical testbeds using a Fourier-transform spectrometer and a vector network analyser, demonstrated performance closely matching the finite-element analysis simulations, viz., greater than 99% absorbance for both polarisations, with only 0.2% difference, across the frequency band of 80-400 GHz. The angular stability for up to +/-10deg. has been confirmed by simulations. To the best of the authors knowledge, this is the first successful implementation of a low-profile ultrawideband metamaterial absorber for this frequency range and operating conditions.