Numerical Study of Ultra-Broadband Metamaterial Perfect Absorber Based on Four-Corner Star Array

Cheng, Yu; Xiong, Min; Chen, Ming; Deng, Shijie; Liu, Houquan; Teng, Chuanxin; Yang, Hongyan; Deng, Hongchang; Yuan, Libo

doi:10.3390/nano11092172

Cited by 14 publications

(5 citation statements)

References 29 publications

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“…Therefore, the ultra-wideband absorption of this model is a combination of different microstructures and higher-order resonance modes. Cheng et al 51 proposed to increase the absorption bandwidth by increasing the resonance mechanism. The structure is a quadrangular star array.…”

Section: Design Of the Metamaterials Perfect Absorbermentioning

confidence: 99%

Structures, principles, and properties of metamaterial perfect absorbers

Zhao,

Wang,

et al. 2023

Phys. Chem. Chem. Phys.

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Section: Design Of the Metamaterials Perfect Absorbermentioning

confidence: 99%

Structures, principles, and properties of metamaterial perfect absorbers

Zhao,

Wang,

et al. 2023

Phys. Chem. Chem. Phys.

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“…In addition, titanium is not as pricey as precious metals. Ti exhibits good plasmonic resonance and significant intrinsic loss in the visible (VIS) to near-infrared (NIR) range, which is conducive to the amplification of plasmonic absorption in this spectral range [23,25]. The requirements of solar thermal photovoltaic systems can be met by these features.…”

Section: Introductionmentioning

confidence: 99%

Optimizing the design of ultra-broadband perfect absorber based on hexagonal lattice of titanium (Ti) parabolic nanoarrays

Vishwakarma,

Joseph

2024

Metamaterials XIV

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Solar energy is a clean and renewable energy source that solves energy and climate emergencies. The near-perfect broadband solar absorbers can offer necessary technical assistance to follow this route and develop an effective solar energy-harvesting system. This work designed a metamaterial perfect absorber that operates in the ultraviolet to nearinfrared spectral range. It is made up of titanium (Ti) parabolic nanoarrays with a hexagonal lattice structure. By using the commercially available 3D-electromagnetic simulator (Lumerical FDTD) operating in the finite-difference time-domain approach, we have found the strong absorption (> 90%) of the absorber across the broadband range of the wavelength 200-3000 nm. Furthermore, we observed that increasing the height of nano-pillars can lead to an expansion in the bandwidth of the absorber. Our study highlights the significant roles played by the localized surface plasmon resonances of Ti parabolic nanoarrays, the inherent loss of titanium material, and the coupling of resonance modes between adjacent parabolic nanoarrays in facilitating this broadband perfect absorption phenomenon. Additionally, we demonstrate that the absorber exhibits some excellent features desirable for the practical absorption and harvesting of solar energy, such as precision tolerance, polarization independence, and large angular acceptance.

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“…These devices have contributed to the development of the application of metamaterials. Absorbers, as one of the extremely important types, have potential applications in solar thermal energy harvesting, 6 optical switching, 7 electromagnetic stealth, 8 etc. After the emergence of tunable single-peak narrow-band absorbers, 9 double-band, 10 multiband, 11 and broadband absorbers 12 have become the hot research topics in recent years.…”

Section: Introductionmentioning

confidence: 99%

Tunable ultrawideband perfect absorber based on vanadium dioxide

et al. 2023

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An ultrawideband metamaterial perfect absorber based on vanadium dioxide is proposed. It achieves >95% absorption of vertically incident electromagnetic waves in the range of 3.50 to 10 THz. The absorption intensity can be dynamically adjusted in the range of 0.2% to 99.98% by varying the conductivity of VO 2 . The mechanism of ultrawideband perfect absorption is interpreted using electric field distribution analysis and impedance-matching theory. The absorption rate related to the structural parameters of the absorber is investigated by numerical simulation. Finally, its polarization angle-insensitive and incidence angle-insensitive properties are demonstrated. This proposed absorber has potential applications in optical switching, electromagnetic stealth, and sensing applications.

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Numerical Study of Ultra-Broadband Metamaterial Perfect Absorber Based on Four-Corner Star Array

Cited by 14 publications

References 29 publications

Structures, principles, and properties of metamaterial perfect absorbers

Structures, principles, and properties of metamaterial perfect absorbers

Optimizing the design of ultra-broadband perfect absorber based on hexagonal lattice of titanium (Ti) parabolic nanoarrays

Tunable ultrawideband perfect absorber based on vanadium dioxide

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