Ultra-broadband infrared metamaterial absorber based on MDMDM structure for optical sensing

被引：2

作者：

Li, Fengjie ^{[1
]}

Du, Jiansen ^{[2
]}

Wang, Shang ^{[3
]}

Yu, Ruitao ^{[1
]}

Wang, Xi ^{[4
]}

Zhang, Tiqiang ^{[1
]}

Chi, Zongtao ^{[1
]}

Wang, Bin ^{[1
]}

Li, Ning ^{[5
]}

机构：

[1] Qingdao Univ, Coll Elect Informat, Micronano Technol Coll, Qingdao, Peoples R China

[2] Qingdao Int Travel Healthcare Ctr, Qingdao, Peoples R China

[3] North China Inst Sci & Technol, Coll Sci, Yanjiao, Peoples R China

[4] China Tobacco Shandong Qingdao Tobacco Co Ltd, Logist Ctr, Qingdao, Peoples R China

[5] Qingdao Univ, Sch Basic Med, Qingdao, Peoples R China

来源：

FRONTIERS IN ASTRONOMY AND SPACE SCIENCES | 2024年 / 10卷

关键词：

metamaterials; broadband; absorber; infrared; imaging; PERFECT ABSORBER; ABSORPTION;

D O I：

10.3389/fspas.2023.1338284

中图分类号：

P1 [天文学];

学科分类号：

0704 ;

摘要：

Infrared observation is a crucial tool in the study of astronomical celestial bodies. Metamaterials have a vast prospect for applications in the field of optics due to their unique electromagnetic tunable characteristics. In order to obtain an ultra-broadband high absorption material in the infrared region, we proposed a metal-dielectric-metal-dielectric-metal (MDMDM) metamaterial absorber using a titanium (Ti) nano-cross layer based on surface plasmon polariton (SPP) resonance and magnetic resonance cavity principles. The geometrical parameters of each layer have been examined carefully. The influence of incident angle from 0 degrees to 60 degrees is investigated for transverse electric and transverse magnetic plane-waves. Near-perfect absorption performance is achieved from near-infrared to mid-infrared region. The average absorption reaches as high as 97.41% from 2.05 to 6.08 mu m. The absorber exhibits polarization-sensitive characteristics. The absorption peaks are 99.50% and 99.80% at 2.55 and 5.24 mu m, respectively. The proposed material has potential applications in astronomical imaging, volcano and fire detection, remote sensing, biological monitoring, and other optical devices.

引用

页数：11

共 50 条

[1] Ultra-broadband metamaterial absorber in the far infrared
Wang, Simin
Du, Jiansen
Chi, Zongtao
Cong, Hailin
Wang, Bin
MATERIALS LETTERS, 2024, 355
[2] Ultra-broadband near-infrared metamaterial absorber
Ding, Fei
Jin, Yi
He, Sailing
2012 ASIA COMMUNICATIONS AND PHOTONICS CONFERENCE (ACP), 2012,
[3] Ultra-broadband metamaterial absorber based on the structure of resistive films
Ling, Xinyan
Xiao, Zhongyin
Zheng, Xiaoxia
Tang, Jingyao
Xu, Kaikai
JOURNAL OF ELECTROMAGNETIC WAVES AND APPLICATIONS, 2016, 30 (17) : 2325 - 2333
[4] An Infrared Ultra-Broadband Absorber Based on MIM Structure
Li, Meichen
Wang, Guan
Gao, Yang
Gao, Yachen
NANOMATERIALS, 2022, 12 (19)
[5] A Tunable Ultra-Broadband Metamaterial Absorber with Multilayered Structure
Rina Dao
Xinru Kong
Hai-Feng Zhang
Xingliang Tian
Plasmonics, 2020, 15 : 169 - 175
[6] A Tunable Ultra-Broadband Metamaterial Absorber with Multilayered Structure
Dao, Rina
Kong, Xinru
Zhang, Hai-Feng
Tian, Xingliang
PLASMONICS, 2020, 15 (01) : 169 - 175
[7] Ultra-Broadband Infrared Metamaterial Absorber for Passive Radiative Cooling
刘彦宁
翁小龙
张澎
李文新
宫禹
张丽
韩天成
周佩珩
邓龙江
Chinese Physics Letters, 2021, 38 (03) : 66 - 71
[8] Ultra-broadband metamaterial absorber for infrared transparency window of the atmosphere
Li, Ling
Chen, Hongjie
Xie, Zhengwei
Chen, Weidong
Zhang, Wenpeng
Liu, Wuming
PHYSICS LETTERS A, 2019, 383 (36)
[9] Ultra-Broadband Infrared Metamaterial Absorber for Passive Radiative Cooling
Liu, Yan-Ning
Weng, Xiao-Long
Zhang, Peng
Li, Wen-Xin
Gong, Yu
Zhang, Li
Han, Tian-Cheng
Zhou, Pei-Heng
Deng, Long-Jiang
CHINESE PHYSICS LETTERS, 2021, 38 (03)
[10] Ultra-broadband nanowire metamaterial absorber
Wang, Baoqing
Ma, Cuiping
Yu, Peng
Govorov, Alexander O.
Xu, Hongxing
Wang, Wenhao
Besteiro, Lucas V.
Jing, Zhimin
LI, Peihang
Wang, Zhiming
PHOTONICS RESEARCH, 2022, 10 (12) : 2718 - 2727

← 1 2 3 4 5 →