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@article{abdulkarim_review_2022,
title = {A Review on Metamaterial Absorbers: Microwave to Optical},
volume = {10},
issn = {2296-424X},
url = {https://www.frontiersin.org/articles/10.3389/fphy.2022.893791/full},
doi = {10.3389/fphy.2022.893791},
shorttitle = {A Review on Metamaterial Absorbers},
abstract = {Metamaterials ({MM}) are artificially designed materials that possess unique properties due to their geometrical design. They also display some peculiar properties, such as negative refractive index, Snell’s law reversal, Doppler effect reverse, and left-handed behavior. {MMs} are used in a myriad of applications, including invisibility cloaking, perfect lensing, perfect absorption, and sensing. In this review article, the property of electromagnetic absorption by structures known as metamaterial absorbers ({MMAs}) is discussed. An {MMA} is a composite made up of many layers of metallic patterns separated by dielectric. This novel device helps in achieving near-unity absorption by various mechanisms, which are investigated in this article. The {MMAs} are classified based on their absorption characteristics, such as polarization tunability, broadband operation, and multiband absorption, in different frequency regimes.},
pages = {893791},
journaltitle = {Frontiers in Physics},
shortjournal = {Front. Phys.},
author = {Abdulkarim, Yadgar I. and Mohanty, Ayesha and Acharya, Om Prakash and Appasani, Bhargav and Khan, Mohammad S. and Mohapatra, S. K. and Muhammadsharif, Fahmi F. and Dong, Jian},
urldate = {2024-10-03},
date = {2022-04-29},
langid = {english},
file = {Abdulkarim et al. - 2022 - A Review on Metamaterial Absorbers Microwave to O.pdf:C\:\\Users\\marko\\Zotero\\storage\\8EBE4F2U\\Abdulkarim et al. - 2022 - A Review on Metamaterial Absorbers Microwave to O.pdf:application/pdf},
}
@article{biswas_ultra-wideband_2022,
title = {An ultra-wideband origami microwave absorber},
volume = {12},
issn = {2045-2322},
url = {https://www.nature.com/articles/s41598-022-17648-4},
doi = {10.1038/s41598-022-17648-4},
abstract = {Abstract
Microwave absorbers have been used to mitigate signal interference, and to shield electromagnetic systems. Two different types of absorbers have been presented: (a) low-cost narrowband absorbers that are simple to manufacture, and (b) expensive wideband microwave absorbers that are based on complex designs. In fact, as designers try to increase the bandwidth of absorbers, they typically increase their complexity with the introduction of several electromagnetic components (e.g., introduction of multi-layer designs, introduction of multiple electromagnetic resonators, etc.,), thereby increasing their fabrication cost. Therefore, it has been a challenge to design wideband absorbers with low cost of fabrication. To address this challenge, we propose a novel design approach that combines origami math with electromagnetics to develop a simple to manufacture ultra-wideband absorber with minimal fabrication and assembly cost. Specifically, we utilize a Tachi–Miura origami pattern in a honeycomb configuration to create the first absorber that can maintain an absorptivity above 90\% in a 24.6:1 bandwidth. To explain the ultra-wideband behavior of our absorber, we develop analytical models based on the transmission-reflection theory of electromagnetic waves through a series of inhomogeneous media. The ultra-wideband performance of our absorber is validated and characterized using simulations and measurements.},
pages = {13449},
number = {1},
journaltitle = {Scientific Reports},
shortjournal = {Sci Rep},
author = {Biswas, Akash and Zekios, Constantinos L. and Ynchausti, Collin and Howell, Larry L. and Magleby, Spencer P. and Georgakopoulos, Stavros V.},
urldate = {2024-10-03},
date = {2022-08-04},
langid = {english},
file = {Biswas et al. - 2022 - An ultra-wideband origami microwave absorber.pdf:C\:\\Users\\marko\\Zotero\\storage\\DZUX83FC\\Biswas et al. - 2022 - An ultra-wideband origami microwave absorber.pdf:application/pdf},
}
@article{jha_design_2018,
title = {Design of a compact microwave absorber using parameter retrieval method for wireless communication applications},
volume = {12},
rights = {http://onlinelibrary.wiley.com/{termsAndConditions}\#vor},
issn = {1751-8733, 1751-8733},
url = {https://onlinelibrary.wiley.com/doi/10.1049/iet-map.2017.0785},
doi = {10.1049/iet-map.2017.0785},
abstract = {A novel compact microwave absorber with 10 {dB} absorption level in 1.8–2.1 {GHz} frequency band for the wireless communication applications is investigated. A robust equivalent circuit ({EC}) model of the structure is developed and rigorously analysed using a non-resonance constituent parameter extraction technique. The {EC} model and the proposed topology developed on a low-cost {FR}-4 substrate of thickness 0.048{λL} (λL = wavelength at lower operating frequency) have been analysed for different polarisations and are in close agreement with each other. The structure has also been experimentally verified and good agreement among analytical model, full wave simulation, and the experimental results is observed. The absorber shows the high cost-effective bandwidth ({BWCE} = 81.14) in comparison to many recently reported works which proves its compactness and novelty.},
pages = {977--985},
number = {6},
journaltitle = {{IET} Microwaves, Antennas \& Propagation},
shortjournal = {{IET} Microwaves, Antennas \& Propagation},
author = {Jha, Kumud Ranjan and Mishra, Ghanshyam and Sharma, Satish K.},
urldate = {2024-11-05},
date = {2018-05},
langid = {english},
file = {Jha et al. - 2018 - Design of a compact microwave absorber using param.PDF:C\:\\Users\\marko\\Zotero\\storage\\SJNHFT2I\\Jha et al. - 2018 - Design of a compact microwave absorber using param.PDF:application/pdf},
}
@article{veselago_left_2006,
title = {The left hand of brightness: past, present and future of negative index materials},
volume = {5},
rights = {https://www.springer.com/tdm},
issn = {1476-1122, 1476-4660},
url = {https://www.nature.com/articles/nmat1746},
doi = {10.1038/nmat1746},
shorttitle = {The left hand of brightness},
pages = {759--762},
number = {10},
journaltitle = {Nature Materials},
shortjournal = {Nature Mater},
author = {Veselago, V. G. and Narimanov, E. E.},
urldate = {2024-11-05},
date = {2006-10-01},
langid = {english},
file = {Veselago and Narimanov - 2006 - The left hand of brightness past, present and fut.pdf:C\:\\Users\\marko\\Zotero\\storage\\B5WZSH2W\\Veselago and Narimanov - 2006 - The left hand of brightness past, present and fut.pdf:application/pdf},
}
@article{zhang_design_2023,
title = {Design and Analysis of a Broadband Microwave Metamaterial Absorber},
volume = {15},
rights = {https://creativecommons.org/licenses/by/4.0/legalcode},
issn = {1943-0655, 1943-0647},
url = {https://ieeexplore.ieee.org/document/10129034/},
doi = {10.1109/JPHOT.2023.3277449},
abstract = {In this article, a broadband metamaterial absorber suitable for the S, C, and X bands is designed and manufactured. The absorber is made of {FR}-4 substrate, resonant metal structure, lumped resistance, and metal backplate, has a unit size of 0.11{λL}, and a total thickness of 0.084{λL}. The absorption principle of the absorber is analyzed using equivalent medium theory and parametric research. The calculation results show that the absorber achieves more than 90\% broadband absorption (relative bandwidth of 130\%) between 2.7 {GHz} and 12.7 {GHz}, has a good polarization angle and incidence angle insensitivity, uses electromagnetic resonance to explain its absorption characteristics, and experiments confirm that the absorber has good broadband absorption. The proposed absorber has higher absorption and simpler construction than the previously described broadband absorber, and it has the potential for practical applications in {EMC}, radar, and electromagnetic protection.},
pages = {1--10},
number = {3},
journaltitle = {{IEEE} Photonics Journal},
shortjournal = {{IEEE} Photonics J.},
author = {Zhang, Yufei and Yang, Wenrong and Li, Xiaonan and Liu, Guoqiang},
urldate = {2024-11-05},
date = {2023-06},
langid = {english},
file = {Zhang et al. - 2023 - Design and Analysis of a Broadband Microwave Metam.pdf:C\:\\Users\\marko\\Zotero\\storage\\FHS4KG9R\\Zhang et al. - 2023 - Design and Analysis of a Broadband Microwave Metam.pdf:application/pdf},
}
@article{tran_broadband_2020,
title = {Broadband microwave coding metamaterial absorbers},
volume = {10},
issn = {2045-2322},
url = {https://www.nature.com/articles/s41598-020-58774-1},
doi = {10.1038/s41598-020-58774-1},
abstract = {Abstract
In this paper, a broadband metamaterial microwave absorber is designed, simulated and measured. Differently from the traditional method which is only based on unit cell boundary conditions, we carried out full-wave finite integration simulations using full-sized configurations. Starting from an elementary unit cell structure, four kinds of coding metamaterial blocks, 2 × 2, 3 × 3, 4 × 4 and 6 × 6 blocks were optimized and then used as building blocks (meta-block) for the construction of numerous 12 × 12 topologies with a realistic size scale. We found the broadband absorption response in the frequency range 16 {GHz} to 33 {GHz}, in good agreement with the equivalent medium theory prediction and experimental observation. Considering various applications of metamaterials or metamaterial absorbers in the electromagnetic wave processing, including the radars or satellite communications, requires the frequency in the range up to 40 {GHz}. Our study could be useful to guide experimental work. Furthermore, compared to the straightforward approach that represents the metamaterials configurations as 12 × 12 matrices of random binary bits (0 and 1), our new approach achieves significant gains in the broadband absorption. Our method also may be applied to the full-sized structures with arbitrary dimensions, and thus provide a useful tool in the design of metamaterials with specific desired frequency ranges.},
pages = {1810},
number = {1},
journaltitle = {Scientific Reports},
shortjournal = {Sci Rep},
author = {Tran, Manh Cuong and Pham, Van Hai and Ho, Tuan Hung and Nguyen, Thi Thuy and Do, Hoang Tung and Bui, Xuan Khuyen and Bui, Son Tung and Le, Dac Tuyen and Pham, The Linh and Vu, Dinh Lam},
urldate = {2024-11-05},
date = {2020-02-04},
langid = {english},
file = {Tran et al. - 2020 - Broadband microwave coding metamaterial absorbers.pdf:C\:\\Users\\marko\\Zotero\\storage\\J3L9QYSK\\Tran et al. - 2020 - Broadband microwave coding metamaterial absorbers.pdf:application/pdf},
}
@article{wang_simulationguided_2024,
title = {Simulation‐Guided Design of Gradient Multilayer Microwave Absorber with Tailored Absorption Performance},
volume = {309},
issn = {1438-7492, 1439-2054},
url = {https://onlinelibrary.wiley.com/doi/10.1002/mame.202400015},
doi = {10.1002/mame.202400015},
abstract = {Abstract
Flexible microwave absorber ({MAR}), vital in advanced applications such as wearable electronics and precision devices, are highly valued for their lightweight, exceptional electromagnetic waves ({EWs}), and ease of fabrication. However, optimizing the electromagnetic parameters of microwave absorption materials ({MAMs}) to enhance absorption ability and expand effective absorption broadband ({EAB}, reflection loss ({RL}) {\textless}−10 {dB}) is a considerable challenge. Herein, a permittivity‐attenuation evaluation diagram ({PAED}) is constructed using parameter scanning based on the Materials Genome Initiative to determine the ideal electromagnetic parameters and thickness, optimize absorption efficiency, and obtain highly efficient absorbers. Guided by the {PAED}, a multilayer {MAR} consisting of a “matching‐absorption‐reflection layer” and a dielectric loss gradient aligned with the direction of {EWs} propagation is developed. This design significantly enhances the {EWs} penetration and ensures effective absorption, attributed to the well‐matched impedance and attenuation characteristics. As anticipated, the microwave absorption of the absorber (density = 0.063 g cm
−3
) is optimized, with an {RL} of −34 {dB} at
d
= 4 mm and an {EAB} covering the entire X‐band (8.2–12.4 {GHz}). This study presents a novel approach for establishing a material database for {MAMs} and developing high‐performance absorbers characterized by thinness, lightness, broad operational frequency range, and robust absorption capacity.},
pages = {2400015},
number = {9},
journaltitle = {Macromolecular Materials and Engineering},
shortjournal = {Macro Materials \& Eng},
author = {Wang, Ye and Lv, Chunzheng and Zhang, Xuan and Liu, Xingang and Zhang, Chuhong},
urldate = {2024-11-05},
date = {2024-09},
langid = {english},
file = {Wang et al. - 2024 - Simulation‐Guided Design of Gradient Multilayer Mi.pdf:C\:\\Users\\marko\\Zotero\\storage\\5B5QKKLB\\Wang et al. - 2024 - Simulation‐Guided Design of Gradient Multilayer Mi.pdf:application/pdf},
}