Radio-transparent multi-layer insulation for radiowave receivers

TL;DR

This paper introduces radio-transparent multi-layer insulation (RT-MLI), a novel layered insulator that allows large radiowave receiver apertures to stay cold by blocking infrared radiation while transmitting radio frequencies, enhancing receiver performance.

Contribution

The paper presents RT-MLI, a new multi-layer insulation technology that effectively reduces thermal load in radiowave detectors without requiring thermal links or anti-reflection coatings.

Findings

RT-MLI with 12 layers transmits over 95% of radio waves below 200 GHz

RT-MLI significantly reduces thermal radiation load

Successful cooling demonstrated in a 200 mm aperture system

Abstract

In the field of radiowave detection, enlarging the receiver aperture to enhance the amount of light detected is essential for greater scientific achievements. One challenge in using radio transmittable apertures is keeping the detectors cool. This is because transparency to thermal radiation above the radio frequency range increases the thermal load. A technology that maintains cold conditions while allowing larger apertures has been long-awaited. We propose radio-transparent multi-layer insulation (RT-MLI), composed from a set of stacked insulating layers. The insulator is transparent to radio frequencies, but not transparent to infrared radiation. The basic idea for cooling is similar to conventional multi-layer insulation. It leads to a reduction in thermal radiation while maintaining a uniform surface temperature. The advantage of this technique over other filter types is that no thermal links are required. As insulator material, we used foamed polystyrene; its low index of refraction makes an anti-reflection coating unnecessary. We measured the basic performance of RT-MLI to confirm that thermal loads are lowered with more layers. We also confirmed that our RT-MLI has high transmittance to radiowaves, but blocks infrared radiation. For example, RT-MLI with 12 layers has a transmittance greater than 95% (lower than 1%) below 200 GHz (above 4 THz). We demonstrated its effects in a system with absorptive-type filters, where aperture diameters were 200 mm. Low temperatures were successfully maintained for the filters. We conclude that this technology significantly enhances the cooling of radiowave receivers, and is particularly suitable for large-aperture systems. This technology is expected to be applicable to various fields, including radio astronomy, geo-environmental assessment, and radar systems.