Abstract-Two-Terminal Graphene Oxide Devices for Electrical Modulation of Broadband Terahertz Waves

1. 1. 
      
2. Seungwoo Lee^1,*, 
3. Kyung Eun Lee², 
4. Won Jun Lee², 
5. Byung Cheol Park³, 
6. Byungsoo Kang³, 
7. Euyheon Hwang^4,* and
8. Sang Ouk Kim^2,*

Article first published online: 16 DEC 2015

DOI: 10.1002/adom.201500577

© 2015 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

http://onlinelibrary.wiley.com/doi/10.1002/adom.201500577/abstract;jsessionid=7B118B09A2FC6E009805CF6701D21B98.f01t03?userIsAuthenticated=false&deniedAccessCustomisedMessage=

Graphene oxide (GO) can provide a generic way to effectively control broadband THz transmission amplitude, when incorporated into two-terminal electrode devices. Electrically trapped charge carriers within localized impurity states (LIS) of GO, which originate from fully randomized defective structure of GO, result in a large modulation of transmission amplitude (≈30%) for broadband THz waves (≈0.3–2.0 THz) even at room temperature.

Abstract-Design of optical metamaterial mirror with metallic nanoparticles for floating-gate graphene optoelectronic devices

Seungwoo Lee and Juyoung Kim
https://www.osapublishing.org/oe/abstract.cfm?uri=oe-23-17-21809

The purpose of this work is to conceive the idea for using the gate dielectrics of floating-gate memory device (i.e., Au nanoparticle (AuNP) monolayer embedded within polymeric matrix) as a magnetic mirror, so as to harness the broadband light absorption of thin film optoelectronics. In particular, we systematically examined whether the versatile assembly of spherical AuNP monolayer can be indeed treated as the effective magnetic mirror for floating-gate graphene optoelectronic device. High amenability of the AuNP assembly with the large-area device fabrication procedures may make this strategy widely applicable to various thin film optoelectronic devices. Our study thereby advances the design of mirror for thin film optoelectronics.

© 2015 Optical Society of America

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Switching terahertz waves with gate-controlled active graphene metamaterials

http://graphenetimes.com/2012/09/switching-terahertz-waves-with-gate-controlled-active-graphene-metamaterials/

Authors: Seung Hoon Lee, Muhan Choi, Teun-Teun Kim, Seungwoo Lee, Ming Liu, Xiaobo Yin, Hong Kyw Choi, Seung S. Lee, Choon-Gi Choi, Sung-Yool Choi, Xiang Zhang & Bumki Min

The extraordinary electronic properties of graphene provided the main thrusts for the rapid advance of graphene electronics. In photonics, the gate-controllable electronic properties of graphene provide a route to efficiently manipulate the interaction of photons with graphene, which has recently sparked keen interest in graphene plasmonics. However, the electro-optic tuning capability of unpatterned graphene alone is still not strong enough for practical optoelectronic applications owing to its non-resonant Drude-like behaviour. Here, we demonstrate that substantial gate-induced persistent switching and linear modulation of terahertz waves can be achieved in a two-dimensional metamaterial, into which an atomically thin, gated two-dimensional graphene layer is integrated. The gate-controllable light–matter interaction in the graphene layer can be greatly enhanced by the strong resonances of the metamaterial. Although the thickness of the embedded single-layer graphene is more than six orders of magnitude smaller than the wavelength (<λ/1,000,000), the one-atom-thick layer, in conjunction with the metamaterial, can modulate both the amplitude of the transmitted wave by up to 47% and its phase by 32.2° at room temperature. More interestingly, the gate-controlled active graphene metamaterials show hysteretic behaviour in the transmission of terahertz waves, which is indicative of persistent photonic memory effects.

Nature Materials. doi:10.1038/nmat3433

Abstract-Metamaterials: Reversibly Stretchable and Tunable Terahertz Metamaterials with Wrinkled Layouts

Seungwoo Lee,  Seongnam Kim,  Teun-Teun Kim,  Yushin Kim,  Muhan Choi,  Seung Hoon Lee,  Ju-Young Kim,  Bumki Min 

http://onlinelibrary.wiley.com/doi/10.1002/adma.201290159/abstract

When metamaterials are arranged in a stretchable platform, their practical applications (e.g., reconfigurable optoelectronic devices and biological sensors) can be greatly extended. B. Min and co-workers take inspiration from the wrinkled structures of various bio-organisms to develop a generic strategy for reversibly stretchable metamaterials. The structural integrities of the wrinkled THz metamaterials described, remain intact after repeated stretching/relaxing, and the wrinkled metamaterial makes a mechanically reversible transition between artificial homogeneous and inhomogeneous broadenings