Your search keyword '"Xu, Xibin"' showing total 4 results

1. Plasmonic Absorption Enhancement in Elliptical Graphene Arrays.

Author

Chen, Jiajia, Zeng, Yu, Xu, Xibin, Chen, Xifang, Zhou, Zigang, Shi, Pengcheng, Yi, Zao, Ye, Xin, Xiao, Shuyuan, and Yi, Yougen

Subjects

ABSORPTION, GRAPHENE, ABSORPTION spectra

Abstract

In this paper, we come up with a wavelength tunable absorber which is made up of periodically elliptical graphene arrays in the far-infrared and terahertz regions. Through simulation, we find that we can increase the length of long axis of the ellipse, raise the incidence angles of TM- and TE-polarization (TM- and TE-polarization indicate the direction of the incident electric field along the direction of the x and the y axis, respectively.) within certain limits, and increase the chemical potential of graphene, so as to enhance the absorption of light in the elliptical graphene arrays. We also compare the absorption spectra of the original structure and the complementary structure, and find that the absorption of the original structure is higher than that of the complementary structure. In the end, we study the changes in the absorption rate of the double layer structure of the elliptical array with the increase in the thickness of SiO2. The elliptical array structure can be applied to tunable spectral detectors, filters and sensors at far-infrared and terahertz wavelengths. [ABSTRACT FROM AUTHOR]

Published

2018

2. A tunable broadband absorber in the terahertz band based on the proportional structure of a single layer of graphene.

Author

Lu, Wenqiang, Yi, Zao, Zhang, Jianguo, Xu, Xibin, Tang, Bin, Li, Gongfa, Zeng, Liangcai, Chen, Jing, and Sun, Tangyou

Subjects

*GRAPHENE, *ELECTRIC field effects, *COPPER-zinc alloys, *ELECTROMAGNETIC waves, *ELECTROMAGNETIC wave absorption, *OPTOELECTRONIC devices

Abstract

This paper presents a novel graphene-based proportional structure for a tunable wideband absorber in the terahertz (THz) frequency range. In order to achieve the ideal design structure, we make the distance between the top graphene structure and the periodic edge remains proportional, enabling excellent absorption with an absorption rate exceeding 90 % within the frequency range of 3.1–6.97 (3.87)THz. Notably, a perfect absorption is achieved at f = 6.5 THz. At f = 4.2 THz, the absorption rate is close to 97 %, and at f = 5.2 THz, the absorption rate is about 91 %. The average absorption rate is 94.6 % in the range of 3.1–6.97 THz. The absorber's impedance is calculated to demonstrate its favorable absorption band. Furthermore, an analysis of the electric field within the absorber reveals the coupling effect of strong electric fields between different regions, leading to the overlapping of absorption peaks and the formation of a wideband response. This allows us to choose regions to combine according to the needs of the application. By adjusting the parameters of the absorber, it exhibits coordinated performance and manufacturing tolerance. Additionally, the absorber shows a certain degree of tolerance to the incident angle of electromagnetic waves. These findings highlight the potential applications of this absorber in optoelectronic devices, THz detection, and stealth technology. [Display omitted] • Through CST calculation, this model can achieve bandwidth absorption in the terahertz frequency band. • Designed through a single layer of graphene with strong adjustability. • The electric field distribution and absorption principle were investigated by structure decomposition. • The model has a wide absorption rate and can achieve THz stealth. [ABSTRACT FROM AUTHOR]

Published

2023

3. Plasmonic absorption characteristics based on dumbbell-shaped graphene metamaterial arrays.

Author

Cen, Chunlian, Chen, Jiajia, Liang, Cuiping, Huang, Jing, Chen, Xifang, Tang, Yongjian, Yi, Zao, Xu, Xibin, Yi, Yougen, and Xiao, Shuyuan

Subjects

*PLASMONICS, *ABSORPTION, *GRAPHENE, *METAMATERIALS, *WAVELENGTHS

Abstract

In this paper, we proposed a theoretical model in the far-infrared and terahertz (THz) bands, which are dumbbell-shaped graphene metamaterial arrays with a combination of graphene nanobelt and two semisphere-suspended heads. We report a detailed theoretical investigation on how to enhance localized electric field and the absorption in the dumbbell-shaped graphene metamaterial arrays. The simulation results show that absorption characteristics can be changed by changing the geometrical parameters of the structure and the Fermi level of graphene . Furthermore, we have discovered that the resonant wavelength is insensitive to TM polarization. In addition, we also find that the double-layer graphene arrays have better absorption characteristics than single-layer graphene arrays. This work allows us to achieve tunable terahertz absorber and may also provide potential applications in optical filter and biochemical sensing. [ABSTRACT FROM AUTHOR]

Published

2018

4. Tunable plasmonic resonance absorption characteries-tics in periodic H-shaped graphene arrays.

Author

Cen, Chunlian, Lin, Hang, Liang, Cuiping, Huang, Jing, Chen, Xifang, Yi, Zao, Tang, Yongjian, Duan, Tao, Xu, Xibin, Xiao, Shuyuan, and Yi, Yougen

Subjects

*GRAPHENE, *PLASMONICS, *NANOELECTRONICS, *NANOSTRUCTURED materials, *CARBON

Abstract

In recent years, as an important plasmonic nanomaterial, graphene has become the focus of research. In our research, we design a tunable plasmonic absorber composed of periodic H-shaped graphene arrays in the far-infrared and terahertz (THz) bands. We numerically investigate the structure parameters and the chemical potential of graphene that influence the optical properties of the periodic H-shaped graphene arrays. Compared with periodic H-shaped graphene arrays, under the same TM polarization, the complementary structure has higher absorption. In addition, the polarization sensitivity of the H-shaped graphene arrays is also investigated. Our research not only investigates the plasmonic resonance absorption characteristics, but also implies important potential applications in integrated optical circuits such as optical storage, ultra-fast plasmonic switches, high performance filters and modulators. [ABSTRACT FROM AUTHOR]

Published

2018