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Part 1: Document Description
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Citation |
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Title: |
Replication Data for: Extended Bound States in the Continuum with Symmetry- Broken Terahertz Dielectric Metasurfaces |
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Identification Number: |
doi:10.21979/N9/81VE6S |
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Distributor: |
DR-NTU (Data) |
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Date of Distribution: |
2021-06-10 |
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Version: |
1 |
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Bibliographic Citation: |
Song Han; Prakash Pitchappa; Wenhao Wang; Yogesh Kumar Srivastava; Mikhail V. Rybin; Ranjan Singh, 2021, "Replication Data for: Extended Bound States in the Continuum with Symmetry- Broken Terahertz Dielectric Metasurfaces", https://doi.org/10.21979/N9/81VE6S, DR-NTU (Data), V1 |
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Citation |
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Title: |
Replication Data for: Extended Bound States in the Continuum with Symmetry- Broken Terahertz Dielectric Metasurfaces |
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Identification Number: |
doi:10.21979/N9/81VE6S |
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Authoring Entity: |
Song Han (Nanyang Technological University) |
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Prakash Pitchappa (Nanyang Technological University) |
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Wenhao Wang (Nanyang Technological University) |
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Yogesh Kumar Srivastava (Nanyang Technological University) |
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Mikhail V. Rybin (ITMO University, Russia) |
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Ranjan Singh (Nanyang Technological University) |
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Software used in Production: |
MATLAB |
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Software used in Production: |
Origin |
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Grant Number: |
MOE2016-T3-1-006 |
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Grant Number: |
MOE2017-T2-1-110 |
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Grant Number: |
RG96/19 |
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Distributor: |
DR-NTU (Data) |
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Access Authority: |
Han Song |
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Access Authority: |
Ranjan Singh |
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Depositor: |
Han Song |
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Date of Deposit: |
2021-06-10 |
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Holdings Information: |
https://doi.org/10.21979/N9/81VE6S |
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Study Scope |
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Keywords: |
Physics, Physics, extended bound states in the continuum, photonic bound states in the continuum, terahertz symmetry-broken metasurfaces, topological charges |
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Abstract: |
Excitation of the non-radiative eigenmodes in photonics and metamaterials above their light cone, that is, the bound states in the continuum (BICs), has drawn fundamental and technological interest. However, the current studies on photonic BICs are mainly restricted to the characterization of the eigenmodes with fixed point group. Here, a fourfold rotationally symmetric (C4v) array of silicon resonators in a square lattice is investigated that reveals the traditional symmetry-protected (Γ-state) and accidental (off-Γ) BICs in the momentum space. Upon symmetry-breaking, BICs at Γ-state transform into quasi-states with decaying quality factors that obey the inverse-square law α−2 as a function of the structural asymmetry parameter α. Surprisingly, at larger asymmetries, multiple new states of extended BICs are observed beyond typical inverse-square law behavior. The structural asymmetry of a resonator provides an important degree of freedom for exploring the Friedrich–Wintgen and new accidental BICs that are topologically protected by robust polarization vortices. The extended family of sharp BIC resonances in all-dielectric silicon metasurfaces is extremely important for scalable applications in terahertz sensing, higher harmonic generation, and ultralow-power switching. |
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Kind of Data: |
MATLAB data & figures |
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Kind of Data: |
Origin data |
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Kind of Data: |
Experimental data |
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Methodology and Processing |
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Sources Statement |
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Data Access |
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Other Study Description Materials |
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Related Publications |
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Citation |
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Identification Number: |
10.1002/adom.202002001 |
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Bibliographic Citation: |
Han, S., Pitchappa, P., Wang, W., Srivastava, Y.K., Rybin, M.V. and Singh, R., (2021). Extended Bound States in the Continuum with Symmetry‐Broken Terahertz Dielectric Metasurfaces. Advanced Optical Materials, 9(7), 2002001. |
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Figure1b bandSturcture.opj |
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Figure1b Inseted AngRes_Transmission.mat |
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Figure1c inset alpha0.1_1stEz.fig |
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Figure1c inset alpha0.1_1stEz.txt |
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Figure1c Inset reEz_xy_mode1.fig |
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Figure1c.opj |
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Figure1d inset alpha0.1_2ndEz.fig |
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Figure1d inset alpha0.1_2ndEz.txt |
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Figure1d Inset reEz_xy_accidBIC.fig |
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Figure1d Inset reEz_xy_mode2.fig |
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Figure1d.opj |
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Figure2a TM1_Qfactor.fig |
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Figure2b TM1_TopologicalCharge.fig |
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Figure2c TM2_Qfactor.fig |
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Figure2d TM2_TopologicalCharge.fig |
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Figure3b ampT_Sweep_DenseDx_Dy0um.txt |
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Figure3b powT_Sweep_DenseDx_Dy0um.fig |
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Figure3c alpha0.005_1stEz.txt |
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Figure3c inset alpha0.005_1stEz.fig |
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Figure3c Qfit_TM1.opj |
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Figure3d alpha0.005_2ndEz.fig |
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Figure3d alpha0.005_2ndEz.txt |
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Figure3d Qfit_TM2.opj |
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Figure4a Extended_BIC1_TopologicalCharge.fig |
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Figure4b Extended_BIC2_TopologicalCharge.fig |
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Figure5a anticrossing.opj |
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Figure5a Band_SweepDx_Dy0um.txt |
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Figure5a Qfactor_SweepDx_Dy0um.txt |
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Figure5b alpha0.34_1stEz.fig |
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Figure5b alpha0.34_1stEz.txt |
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Figure5c alpha0.34_2ndEz.fig |
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Figure5c alpha0.34_2ndEz.txt |
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Figure5d alpha0.4_1stEz.fig |
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Figure5d alpha0.4_1stEz.txt |
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Figure5e alpha0.4_2ndEz.fig |
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Figure5e alpha0.4_2ndEz.txt |
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Figure5f alpha0.5_1stEz.fig |
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Figure5f alpha0.5_1stEz.txt |
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Figure5g alpha0.5_2ndEz.fig |
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Figure5g alpha0.5_2ndEz.txt |
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Figure 6a.tif |
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Figure 6b.tif |
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Figure 6c.tif |
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Figure 7a&b_Exp_Sim.opj |
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Figure 7c_TM_sweepDx_6deg.txt |
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Figure 7d_TM_sweepDx_0deg.txt |
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