Tunable Narrowband Silicon-Based Thermal Emitter with Excellent High-Temperature Stability Fabricated by Lithography-Free Methods

Hou, Guozhi; Wang, Hongtao; Zhu, Yu; Lu, Zhihong; Xu, Jun; Chen, Kunji

doi:10.3390/nano11071814

Cited by 7 publications

(3 citation statements)

References 48 publications

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“…The details of the above two spectrophotometers have been described in our previous work. 54 Thermal annealing experiments were performed using a tube furnace (OTF-1200X-80-II).…”

Section: Methodsmentioning

confidence: 99%

Silicon-based spectrally selective emitters with good high-temperature stability on stepped metasurfaces

et al. 2022

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“…The details of the above two spectrophotometers have been described in our previous work. 54 Thermal annealing experiments were performed using a tube furnace (OTF-1200X-80-II).…”

Section: Methodsmentioning

confidence: 99%

Silicon-based spectrally selective emitters with good high-temperature stability on stepped metasurfaces

et al. 2022

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“…Because a high-quality Lorentzian line-shape emission spectrum cannot compensate for the insufficient emission power caused by compression of the emission in wavelength, [12,48] it leads to a decline in efficiency. Additionally, if the emission spectrum is widened (the quality factor decreases) as in the metasurface-based emitters, [49,50] the Tamm-plasmonbased emitters, [33,51,52] and the CPA-based emitters, [47,53,54] the total system efficiency will be relatively adversely affected compared to the step-function-like spectrum of the thermal emitter because of the tail of spectrum in mid-infrared. If there is a unimodal emission state whose eigenfrequency is certain both in real and imaginary parts (the real part relates to the center frequency of the absorption, and the imaginary part relates to the quality factor) where most of the photon energy is above the bandgap, a Lorentzian line shape shows in emission as shown in Figure 1b.…”

Section: Emitter Design Based On Dceamentioning

confidence: 99%

Spectrum‐Selective High‐Temperature Tolerant Thermal Emitter by Dual‐Coherence Enhanced Absorption for Solar Thermophotovoltaics

Zhang,

Zhong,

Lin

et al. 2023

Advanced Optical Materials

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Solar thermophotovoltaics (STPV) receive considerable attention for the record high energy transfer efficiency beyond conventional photovoltaics systems, which requires a well‐designed structured absorber/emitter and high operating temperature. However, the inherent tradeoff between increased operation temperature and material/structure stability (especially for the thermal emitters) severely hinders the development of STPV. In this work, a new design is proposed for a step‐function‐like thermal emitter based on a two‐path (quasi) coherent perfect absorption effect, which is experimentally enabled by a few‐layer Si/Mo/AlN lamellar film on a Mo substrate through a sequential physical vapor deposition process. The as‐prepared lamellar emitter exhibits maximal emissivity of ≈97% for 1.4 µm with excellent thermal suppression down to 10% across 3.4–10 µm, the performance of which is well maintained up to 973 K. When employed in the established STPV system, the dual coherent enhanced absorption (DCEA) system contributes to an increase of 20% in the total system efficiency compared to the unimodal coherent perfect absorption counterpart. The design proposed in this study provides a new methodology for improving the efficiency of the STPV system and may have significant applications in improving thermal energy regulation for compact systems.

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“…However, the fabricated emitter has a high secondary peak in the longer wavelength region and exhibits poor thermal stability. In a previous study, 26 we designed a TPP-based thermal emitter composed of SiN x / SiN y O z (SiN/SiNO) multilayers and a tungsten (W) film on a silicon (Si) substrate. The proposed emitter achieves nearly unity absorption at the expected wavelength.…”

Section: ■ Introductionmentioning

confidence: 99%

Nanolayered Wavelength-Selective Narrowband Thermal Emitters for Solar Thermophotovoltaics

Wang

Hou

Zhu

et al. 2022

ACS Appl. Nano Mater.

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To enhance the efficiency of a solar thermophotovoltaic system, one of the challenges is to develop a thermal emitter with narrowband emission at a selected wavelength to efficiently match the bandgap of a bottom photovoltaic cell. Here, we propose a nanolayered narrowband thermal emitter with a-SiN x and a-SiN y O z alternatively stacked nanolayers deposited on a polished silicon substrate covered by metallic molybdenum. The fabricated Si-Mo-SiN x /SiN y O z emitters exhibit a good narrowband absorption with an absorptance of above 90% at the designed emission wavelength based on a Tamm plasmon polariton, while the absorption spectra can be tuned by simply changing the thickness of the multilayers. Due to the large imaginary part of the dielectric function of Mo as well as the better stability compared with tungsten (W), a suppressed absorption as low as 1.4% can be achieved within the wavelength region of 2–7 μm and the fabricated emitters exhibit a high resistance to high-temperature treatment in an air atmosphere. The simulated solar thermophotovoltaic system efficiency reaches 28.9% under a solar concentration of 1000 based on the proposed emitter. Such a nanolayered wavelength-selective thermal emitter can be potentially applied in high-performance thermophotovoltaic systems.

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Tunable Narrowband Silicon-Based Thermal Emitter with Excellent High-Temperature Stability Fabricated by Lithography-Free Methods

Cited by 7 publications

References 48 publications

Silicon-based spectrally selective emitters with good high-temperature stability on stepped metasurfaces

Silicon-based spectrally selective emitters with good high-temperature stability on stepped metasurfaces

Spectrum‐Selective High‐Temperature Tolerant Thermal Emitter by Dual‐Coherence Enhanced Absorption for Solar Thermophotovoltaics

Nanolayered Wavelength-Selective Narrowband Thermal Emitters for Solar Thermophotovoltaics

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