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AuthorSumbel, Ijaz
AuthorMehmood, Muhammad Qasim
AuthorAhmed, Zubair
AuthorAljaloud, Khaled A.
AuthorAlqahtani, Ali H.
AuthorAl- Adidi, Yosef
AuthorHussain, Rifaqat
Available date2024-08-08T04:05:42Z
Publication Date2024-08-31
Publication NameMaterials Today Communications
Identifierhttp://dx.doi.org/10.1016/j.mtcomm.2024.109967
URIhttps://www.sciencedirect.com/science/article/pii/S2352492824019482
URIhttp://hdl.handle.net/10576/57488
AbstractElectromagnetic radiations are a key energy source, which, by deploying bandgap-engineered devices, are directed onto PV cells to maximize their utilization. In this regard, the Solar Thermophotovoltaic (STPV) systems are vital, consisting of an intermediate absorber-emitter assembly between sunlight and solar cells. A theoretical and computational demonstration of a highly thermally robust, angularly stable, polarization-insensitive, and compact tungsten-based broadband absorber and spectrally selective emitter in symmetric metal-insulator-metal (W-SiO2-W) configuration has been presented. The nanoscale absorber consists of four differently-sized cylinders forming a supercell, and the emitter is cylindrical. The absorber has been optimized over a range of operating temperatures and solar irradiances, manifesting a very high absorption for the visible region with an average of 98.09 % for 400 – 800 nm, exhibiting > 99 % absorption for a BW of 225 nm with a peak of 99.99 % at 674 nm. The emitter has been optimized with 99.72 % emissivity at the desired spectral location. The absorber’s intermediate efficiency is 99.91 % for 5000 suns at 800 °C, which is as high as 72.33 % at a target temperature of 3200 °C. This study aims to match a higher bandgap of 1.5 eV perovskite solar cells and realize higher efficiency than tandem solar cells. The solar cell efficiency is 42.39 %, which results in solar-to-electricity efficiency of 42.38 %, exceeding the Shockley-Queisser (SQ) limit. As a proof-of-concept using a simulation program SCAPS-1D, a perovskite solar cell is illuminated using a bandgap-matched photon, increasing its efficiency from 26.67 % to 45.79 %. Thus, the presented idea achieves cell efficiency beyond the SQ limit without employing complex tandem cells.
SponsorThe authors would like to acknowledge the support provided by Researchers Supporting Project number (RSP2024R474), King Saud University, Riyadh, Saudi Arabia.
Languageen
PublisherElsevier
SubjectSolar thermophotovoltaic
Solar energy harvesting
Thermally stable
Tungsten-based
Nanostructured
TitleEfficient solar energy harvesting via thermally stable tungsten-based nanostructured solar thermophotovoltaic systems
TypeArticle
Volume Number40
ESSN2352-4928
dc.accessType Full Text


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