Won, Sejeong Jung, Hyun-June Kim, Dasom Lee, Sang-Hun Lam, Do Van Kim, Hyeon-Don Kim, Kwang-Seop Lee, Seung-Mo Seo, Minah Kim, Dai-Sik Lee, Hak-Joo Kim, Jae-Hyun 2024-01-19T18:03:06Z 2024-01-19T18:03:06Z 2021-09-04 2020-03 0008-6223 https://pubs.kist.re.kr/handle/201004/118935 Terahertz (THz) nanoantennas have significant potential for versatile applications in THz spectroscopy because of their capability for strong electromagnetic field localization. Electron-beam lithography or focused ion beam machining is typically employed to fabricate nanoantenna structures. These nanolithography methods present limitations in the widespread utilization of THz nanoantennas because of their high cost and low productivity. In this work, we proposed graphene-based crack lithography as a high throughput fabrication method for nanoantenna structures. A double-layer graphene interface was introduced to enable independent control of the nanoantenna dimensions and provide graphene-based nanoantenna structures. We analyzed the underlying mechanism of graphene-based cracking and developed an analytical model governing the geometric parameters of the fabricated nanostructures. As a vital application of the fabricated nanoantenna structures, we demonstrated the highly sensitive detection of D-Glucose molecules. Graphene-based crack lithography can provide a cost-effective method for generating nanoantenna structures with the desired characteristics and can accelerate the development of practical applications of electromagnetic metamaterials. (C) 2019 Elsevier Ltd. All rights reserved. English PERGAMON-ELSEVIER SCIENCE LTD FRACTURE SPECTROSCOPY NANOWIRES STRAIN DEVICE Graphene-based crack lithography for high-throughput fabrication of terahertz metamaterials Article 10.1016/j.carbon.2019.11.018 1 CARBON, v.158, pp.505 - 512 CARBON 158 505 512 scie scopus 000512995800052 2-s2.0-85075978666 Chemistry, Physical Materials Science, Multidisciplinary Chemistry Materials Science Article FRACTURE SPECTROSCOPY NANOWIRES STRAIN DEVICE