Ultra-Wideband High-Efficiency Solar Absorber and Thermal Emitter Based on Semiconductor InAs Microstructures

Since the use of chemical fuels is permanently damaging the environment, the need for new energy sources is urgent for mankind. Given that solar energy is a clean and sustainable energy source, this study investigates and proposes a six-layer composite ultra-wideband high-efficiency solar absorber w...

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Bibliographic Details
Published in:Micromachines (Basel) 2023-08, Vol.14 (8), p.1597
Main Authors: Zhu, Yanying, Cai, Pinggen, Zhang, Wenlong, Meng, Tongyu, Tang, Yongjian, Yi, Zao, Wei, Kaihua, Li, Gongfa, Tang, Bin, Yi, Yougen
Format: Article
Language:English
Subjects:
Absorption
Aluminum oxide
Boundary conditions
Broadband
Chemical fuels
Clean energy
Climate change
Efficiency
Emitters
Energy sources
Etching
Force and energy
High temperature
Incidence angle
Indium arsenides
Infrared suppression
Ion emission
Light
metamaterial
Metamaterials
Microstructure
Nanostructured materials
Photovoltaic cells
polarization insensitivity
Quantum confinement
Radiation
Reflectance
semiconductor
Semiconductor materials
solar absorber
Solar energy
Solar energy absorbers
Spectrum allocation
Substrates
thermal emitter
Thermal imaging
Thermal radiation
Thermophotovoltaics
ultra-wideband absorption
Ultrawideband
Water purification
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Summary:Since the use of chemical fuels is permanently damaging the environment, the need for new energy sources is urgent for mankind. Given that solar energy is a clean and sustainable energy source, this study investigates and proposes a six-layer composite ultra-wideband high-efficiency solar absorber with an annular microstructure. It achieves this by using a combination of the properties of metamaterials and the quantum confinement effects of semiconductor materials. The substrate is W–Ti–Al2O3, and the microstructure is an annular InAs-square InAs film–Ti film combination. We used Lumerical Solutions’ FDTD solution program to simulate the absorber and calculate the model’s absorption, field distribution, and thermal radiation efficiency (when it is used as a thermal emitter), and further explored the physical mechanism of the model’s ultra-broadband absorption. Our model has an average absorption of 95.80% in the 283–3615 nm band, 95.66% in the 280–4000 nm band, and a weighted average absorption efficiency of 95.78% under AM1.5 illumination. Meanwhile, the reflectance of the model in the 5586–20,000 nm band is all higher than 80%, with an average reflectance of 94.52%, which has a good thermal infrared suppression performance. It is 95.42% under thermal radiation at 1000 K. It has outstanding performance when employed as a thermal emitter as well. Additionally, simulation results show that the absorber has good polarization and incidence angle insensitivity. The model may be applied to photodetection, thermophotovoltaics, bio-detection, imaging, thermal ion emission, and solar water evaporation for water purification.
ISSN:2072-666X
2072-666X
DOI:10.3390/mi14081597