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Mechanically reconfigurable architectured graphene for tunable plasmonic resonances

Authors
Kang, PilgyuKim, Kyoung-HoPark, Hong-GyuNam, SungWoo
Issue Date
13-6월-2018
Publisher
NATURE PUBLISHING GROUP
Citation
LIGHT-SCIENCE & APPLICATIONS, v.7
Indexed
SCIE
SCOPUS
Journal Title
LIGHT-SCIENCE & APPLICATIONS
Volume
7
URI
https://scholar.korea.ac.kr/handle/2021.sw.korea/74936
DOI
10.1038/s41377-018-0002-4
ISSN
2047-7538
Abstract
Graphene nanostructures with complex geometries have been widely explored for plasmonic applications, as their plasmonic resonances exhibit high spatial confinement and gate tunability. However, edge effects in graphene and the narrow range over which plasmonic resonances can be tuned have limited the use of graphene in optical and optoelectronic applications. Here we present a novel approach to achieve mechanically reconfigurable and strongly resonant plasmonic structures based on crumpled graphene. Our calculations show that mechanical reconfiguration of crumpled graphene structures enables broad spectral tunability for plasmonic resonances from mid- to nearinfrared, acting as a new tuning knob combined with conventional electrostatic gating. Furthermore, a continuous sheet of crumpled graphene shows strong confinement of plasmons, with a high near-field intensity enhancement of similar to 1 x 10(4). Finally, decay rates for a dipole emitter are significantly enhanced in the proximity of finite-area biaxially crumpled graphene flakes. Our findings indicate that crumpled graphene provides a platform to engineer graphene-based plasmonics through broadband manipulation of strong plasmonic resonances.
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