Enhancing Solar Thermal Energy Conversion with Silicon-cored Tungsten Nanowire Selective Metamaterial Absorbers

TL;DR

This study develops and experimentally tests silicon-cored tungsten nanowire metamaterial absorbers that significantly improve solar-thermal energy conversion efficiency by enhancing spectral selectivity and reducing heat loss.

Contribution

It introduces a novel fabrication of tungsten nanowire absorbers with superior spectral selectivity and demonstrates their enhanced solar-thermal efficiency through experimental measurements.

Findings

Achieved 41% efficiency at 203°C under 6.3 suns.

Reduced infrared emittance to 0.18, minimizing heat loss.

Projected 74% efficiency at higher stagnation temperatures.

Abstract

This work experimentally studies silicon-cored tungsten nanowire selective metamaterial absorber to enhance solar-thermal energy harvesting, simply fabricated by conformally coating a thin tungsten layer onto a commercial silicon nanowire stamp. Scanning electron microscopy is used to characterize the morphology change before and after the tungsten deposition, while optical spectroscopy is carried out to measure the spectral absorptance (or emittance) in the broad wavelength range from solar spectrum to infrared. It is shown that the tungsten nanowire absorber exhibits almost the same total solar absorptance around 0.85 as the silicon nanowire but with greatly reduced total emittance down to 0.18, which could significantly suppress the infrared emission heat loss. A lab-scale solar-thermal test apparatus is used to measure the solar-thermal efficiency of the tungsten nanowire absorbers from 1 up to 20 suns, experimentally demonstrating the improved performance due to excellent spectral selectivity over the silicon nanowire and black absorbers. With detailed heat transfer analysis, it is found that the tungsten nanowire absorber achieves an experimental efficiency of 41% at temperature 203degC during the solar-thermal test with stagnation temperature 273degC under 6.3 suns. It is projected to reach 74% efficiency at same temperature 203degC with stagnation temperature of 430degC for practical application without parasitic radiative losses from side and bottom surfaces, greatly outperforming the silicon nanowire and black absorbers. The results would facilitate the development of novel metamaterial selective absorbers at low cost for highly-efficient solar thermal energy systems.