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Toroidal Response of Asymmetric Metasurfaces with Multiple High Q-Factor Resonances

Explore the toroidal dipolar resonances in asymmetric metasurfaces using graphene and split ring resonators for THz wave research. This study investigates the interaction between graphene and THz metamaterials to tune resonance frequencies and conductivity.

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Toroidal Response of Asymmetric Metasurfaces with Multiple High Q-Factor Resonances

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  1. Toroidal Response of Asymmetric Metasurfaces with Multiple High Q-Factor Resonances Samuel Gomez Mentor: Sirak M. Mekonen Searles Applied & Materials Physics Laboratory Howard University June 20, 2018

  2. Introduction/Background: Metamaterials • Metamaterials have shown • great capability when it comes to manipulating electromagnetic waves • Composed of unit cells in periodic patterns, which are smaller than the wavelength of the waves they are influencing • Each individual structure composing the material is a “metamolecule”

  3. Recent Progress • Possibilities for negative indexes of refraction • Beam-forming applications have been explored through use of gradient metasurfaces • Metasurfaces make possible a high quality factor, which would be useful for sensing and slow-light devices, as well as precise measurement of small resonance shifts • Additionally, with regards to beam control, non-uniform metasurfaces have a greater degree of freedom • THz waves, which are studied through the use of metamaterials, offer a higher spatial resolution, as well as a nonionizing effect

  4. Graphene capabilities in metamaterial/THz wave research • Graphene is a very intriguing material, as its properties can be modified in order to produce certain results in research • Its fermi level can me modified through an applied gate voltage • By putting sheets of graphene in contact with metasurfaces, we can tune the resonance frequency of the composite • By stacking sheets of the them, you can modify the optical conductivity of the graphene • Graphene has optical transparency, high electron mobility, and it is flexible • Has plasmons (collective oscillations of charge carriers) • Interestingly, at plasmon resonance, THz optical conductivity of patterned graphene becomes independent of frequency

  5. Split Ring Resonators (SRR) • Split rings resonators are composed of various geometries, and it is through these that you can tune responses to THz waves Ramdass, Adrian, et al. “Using a Split Ring Resonator to Harvest RF Energy from a PCB Transmission Line.” YouTube, YouTube, 19 Apr. 2016, www.youtube.com/watch?v=qVH7E6wMnAE.

  6. Base Structures for each experiment Zheng, Xiaobo. “Tuning the Terahertz Trapped Modes of Conductively Couple Fano-Resonators in Reflectional and Rotational Symmetry.” Optical Materials Express, vol. 8, no. 1, 1 Jan. 2018, pp. 105–118. Chen, Xu, and Wenhui Fan. "Study of theinteractionbetweengraphene and planarterahertzmetamaterialwithtoroidal dipolar resonance." Opticsletters 42.10 (2017): 2034-2037ianyu Xiang, Tao Lei, SenHu, JiaoChen, XiaojunHuang, and Helin Yang • A toroidal dipole is an electromagnetic occurrence that has been observed through experiments using metamaterials. • It is produced by currents flowing on the surface of a torus shape along its meridians. Here, an array of magnetic dipoles are arranged in the “head-to-tail configuration along a torus”.

  7. Group Comparisons (experiments) [1] Chen, Xu, and Wenhui Fan. "Study of theinteractionbetweengraphene and planarterahertzmetamaterialwithtoroidal dipolar resonance." Opticsletters 42.10 (2017): 2034-2037ianyu Xiang, Tao Lei, SenHu, JiaoChen, XiaojunHuang, and Helin Yang

  8. Methodology for SAMPL • One of the main differences in design was the different gap lengths (g1,g2). • Chen et al used the same gap spacing for each gap, also for Opt. Mat. Exp. • Chen et al also used much larger dimensions for their design, in the millimeter range. The periodicity of SAMPL designs was 6 microns less than that of the Opt. Mat. Exp. Structure. • All experiments varied the distances between the gaps and the centers of the material. SAMPL symmetric design

  9. Symmetries + = + = Reflectional preserved Rotational and Reflectional preserved + = + = No symmetry Reflectional preserved

  10. Chen et al vs. Optical Materials Express • The structure used by Chenet al is comparable to the rotational geometry from Opt. Mat. Exp, however its dimensions are larger (mm). • Closer and sharper peaks on the transmission graph than the rotationally symmetric design. • X direction polarized wave (parallel to gaps) • Only rotational symmetry + = Chen, Xu, and Wenhui Fan. "Study of theinteractionbetweengraphene and planarterahertzmetamaterialwithtoroidal dipolar resonance." Opticsletters 42.10 (2017): 2034-2037ianyu Xiang, Tao Lei, SenHu, JiaoChen, XiaojunHuang, and Helin Yang

  11. 60 degree apex SOD Symmetric Case

  12. 90 degree apex SOD Symmetric

  13. 110 degree SOD

  14. Next Steps • Fabrication • Running simulations • Making a poster/writing a paper • Take more data

  15. Acknowledgements • Financial support from the REU Site in Physics at Howard University NSF Award PHY 1659224 is gratefully acknowledged

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