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Broadband Metamaterial Absorbers

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Yu, Peng; Besteiro, Lucas V.; Huang, Yongjun; Wu, Jiang; Fu, Lan; Tan, Hark Hoe; Jagadish, Chennupati; Wiederrecht, P; Govorov, A O; Wang, Zhiming

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The recent rise of metamaterials opens new opportunities for absorbers due to their designed electrodynamic properties and effects, allowing the creation of materials with effective values of permittivity and permeability that are not available in naturally occurring materials. Since their first experimental demonstration in 2008, recent literature has offered great advances in metamaterial perfect absorbers (MMPAs) operating at frequencies from radio to optical. Broadband absorbers are...[Show more]

dc.contributor.authorYu, Peng
dc.contributor.authorBesteiro, Lucas V.
dc.contributor.authorHuang, Yongjun
dc.contributor.authorWu, Jiang
dc.contributor.authorFu, Lan
dc.contributor.authorTan, Hark Hoe
dc.contributor.authorJagadish, Chennupati
dc.contributor.authorWiederrecht, P
dc.contributor.authorGovorov, A O
dc.contributor.authorWang, Zhiming
dc.date.accessioned2020-10-27T00:08:16Z
dc.identifier.issn2195-1071
dc.identifier.urihttp://hdl.handle.net/1885/213159
dc.description.abstractThe recent rise of metamaterials opens new opportunities for absorbers due to their designed electrodynamic properties and effects, allowing the creation of materials with effective values of permittivity and permeability that are not available in naturally occurring materials. Since their first experimental demonstration in 2008, recent literature has offered great advances in metamaterial perfect absorbers (MMPAs) operating at frequencies from radio to optical. Broadband absorbers are indispensable in thermophotovoltaics, photodetection, bolometry, and manipulation of mechanical resonances. Although it is easy to obtain MMPAs with single band or multiband, achieving broadband MMPA (BMMPA) remains a challenge due to the intrinsically narrow bandwidth of surface plasmon polaritons, localized surface plasmon resonances generated on metallic surfaces at nanoscale or high Q‐factor in GHz region. To guide future development of BMMPA, recent progress is reviewed here: the methods to create broadband absorption and their potential applications. The four mainstream methods to achieve BMMPAs are introduced, including planar and vertical element arrangements, their welding with lumped elements and the use of plasmonic nanocomposites, accompanied by the description of other, less common approaches. Following this, applications of BMMPA in solar photovoltaics, photodetection, bolometry, and manipulation of mechanical resonances are reviewed. Finally, challenges and prospects are discussed.
dc.description.sponsorshipThis work was supported by National Basic Research Program of China (Project No. 2013CB933301) and National Natural Science Foundation of China (Project No. 51272038). L.V.B. was supported by China Postdoctoral Science Foundation. A.O.G. was supported by the Volkswagen Foundation (Germany) and via the Chang Jiang (Yangtze River) Chair Professorship (China). G.P.W. acknowledges support from the Center for Nanoscale Materials, a U.S. Department of Energy Office of Science User Facility, and support by the U.S. Department of Energy, Office of Science, under Contract No. DE-AC02-06CH11357. In addition, the authors acknowledge financial support obtained from the Virtual Institute for Theoretical Photonics and Energy. This review is part of the Advanced Optical Materials Hall of Fame article series, which recognizes the excellent contributions of leading researchers to the field of optical materials science.
dc.format.mimetypeapplication/pdf
dc.language.isoen_AU
dc.publisherWiley
dc.rights© 2018 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim
dc.sourceAdvanced Optical Materials
dc.titleBroadband Metamaterial Absorbers
dc.typeJournal article
local.description.notesImported from ARIES
local.identifier.citationvolume7
dc.date.issued2019
local.identifier.absfor100700 - NANOTECHNOLOGY
local.identifier.absfor020504 - Photonics, Optoelectronics and Optical Communications
local.identifier.absfor090606 - Photonics and Electro-Optical Engineering (excl. Communications)
local.identifier.ariespublicationu3102795xPUB389
local.publisher.urlhttps://www.wiley.com/en-gb
local.type.statusPublished Version
local.contributor.affiliationYu, Peng, College of Business and Economics, ANU
local.contributor.affiliationBesteiro, Lucas V., University of Electronic Science and Technology of China
local.contributor.affiliationHuang, Yongjun, University of Electronic Science and Technology of China
local.contributor.affiliationWu, Jiang, University of Electronic Science and Technology of China
local.contributor.affiliationFu, Lan, College of Science, ANU
local.contributor.affiliationTan, Hoe Hark, College of Science, ANU
local.contributor.affiliationJagadish, Chennupati, College of Science, ANU
local.contributor.affiliationWiederrecht, P, Argonne National Laboratory
local.contributor.affiliationGovorov, A O, Ohio State University
local.contributor.affiliationWang, Zhiming, University of Electronic Science and Technology of China
local.description.embargo2037-12-31
local.bibliographicCitation.issue3
local.bibliographicCitation.startpage1
local.bibliographicCitation.lastpage32
local.identifier.doi10.1002/adom.201800995
local.identifier.absseo970109 - Expanding Knowledge in Engineering
local.identifier.absseo970102 - Expanding Knowledge in the Physical Sciences
local.identifier.absseo970110 - Expanding Knowledge in Technology
dc.date.updated2020-07-06T08:21:34Z
local.identifier.scopusID2-s2.0-85055712008
CollectionsANU Research Publications

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