Design and optimization of a SiC thermal emitter/absorber composed of periodic microstructures based on a non-linear method

Spectral and directional control of thermal emission based on excitation of confined electromagnetic resonant modes paves a viable way for the design and construction of microscale thermal emitters/absorbers. In this paper, we present numerical simulation results of the thermal radiative properties...

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Published inChinese physics B Vol. 24; no. 9; pp. 276 - 283
Main Author 王卫杰 赵振国 赵艺 周海京 符策基
Format Journal Article
LanguageEnglish
Published 01.09.2015
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ISSN1674-1056
2058-3834
1741-4199
DOI10.1088/1674-1056/24/9/094213

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Abstract Spectral and directional control of thermal emission based on excitation of confined electromagnetic resonant modes paves a viable way for the design and construction of microscale thermal emitters/absorbers. In this paper, we present numerical simulation results of the thermal radiative properties of a silicon carbide(Si C) thermal emitter/absorber composed of periodic microstructures. We illustrate different electromagnetic resonant modes which can be excited with the structure,such as surface phonon polaritons, magnetic polaritons and photonic crystal modes, and the process of radiation spectrum optimization based on a non-linear optimization algorithm. We show that the spectral and directional control of thermal emission/absorption can be efficiently achieved by adjusting the geometrical parameters of the structure. Moreover, the optimized spectrum is insensitive to 3% dimension modification.
AbstractList Spectral and directional control of thermal emission based on excitation of confined electromagnetic resonant modes paves a viable way for the design and construction of microscale thermal emitters/absorbers. In this paper, we present numerical simulation results of the thermal radiative properties of a silicon carbide(Si C) thermal emitter/absorber composed of periodic microstructures. We illustrate different electromagnetic resonant modes which can be excited with the structure,such as surface phonon polaritons, magnetic polaritons and photonic crystal modes, and the process of radiation spectrum optimization based on a non-linear optimization algorithm. We show that the spectral and directional control of thermal emission/absorption can be efficiently achieved by adjusting the geometrical parameters of the structure. Moreover, the optimized spectrum is insensitive to 3% dimension modification.
Spectral and directional control of thermal emission based on excitation of confined electromagnetic resonant modes paves a viable way for the design and construction of microscale thermal emitters/absorbers. In this paper, we present numerical simulation results of the thermal radiative properties of a silicon carbide (SiC) thermal emitter/absorber composed of periodic microstructures. We illustrate different electromagnetic resonant modes which can be excited with the structure, such as surface phonon polaritons, magnetic polaritons and photonic crystal modes, and the process of radiation spectrum optimization based on a non-linear optimization algorithm. We show that the spectral and directional control of thermal emission/absorption can be efficiently achieved by adjusting the geometrical parameters of the structure. Moreover, the optimized spectrum is insensitive to 3% dimension modification.
Author 王卫杰 赵振国 赵艺 周海京 符策基
AuthorAffiliation Institute of Applied Physics and Computational Mathematics, Beijing 100088, China Software Center for High Performance Numerical Simulation of CAEP, Beijing 100088, China Complicated Electromagnetic Environment Laboratory of CAER Mianyang 621900, China LTCS and Department of Mechanics and Engineering Science, College of Engineering, Peking University, Beijing 100871, China
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Notes Spectral and directional control of thermal emission based on excitation of confined electromagnetic resonant modes paves a viable way for the design and construction of microscale thermal emitters/absorbers. In this paper, we present numerical simulation results of the thermal radiative properties of a silicon carbide(Si C) thermal emitter/absorber composed of periodic microstructures. We illustrate different electromagnetic resonant modes which can be excited with the structure,such as surface phonon polaritons, magnetic polaritons and photonic crystal modes, and the process of radiation spectrum optimization based on a non-linear optimization algorithm. We show that the spectral and directional control of thermal emission/absorption can be efficiently achieved by adjusting the geometrical parameters of the structure. Moreover, the optimized spectrum is insensitive to 3% dimension modification.
11-5639/O4
silicon carbide,radiative heat transfer,photonic crystal,optimization method
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SubjectTerms Directional control
Emittance
Mathematical models
Microstructure
Nonlinearity
Optimization
Polaritons
Silicon carbide
优化算法
吸收器
周期性微结构
热发射
碳化硅
设计
谐振模式
非线性方法
Title Design and optimization of a SiC thermal emitter/absorber composed of periodic microstructures based on a non-linear method
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