Replication Data for: Lattice induced strong coupling and line narrowing of split resonances in metamaterials (doi:10.21979/N9/UMA5GK)

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Document Description
Citation
Title:	Replication Data for: Lattice induced strong coupling and line narrowing of split resonances in metamaterials
Identification Number:	doi:10.21979/N9/UMA5GK
Distributor:	DR-NTU (Data)
Date of Distribution:	2020-04-30
Version:	2
Bibliographic Citation:	Thomas Tan Caiwei; Yogesh Kumar Srivastava; Manukumara Manjappa; Eric Plum; Ranjan Singh, 2020, "Replication Data for: Lattice induced strong coupling and line narrowing of split resonances in metamaterials", https://doi.org/10.21979/N9/UMA5GK, DR-NTU (Data), V2, UNF:6:PJXrGIhBxyvUWgNaWWPejg== [fileUNF]
Study Description
Citation
Title:	Replication Data for: Lattice induced strong coupling and line narrowing of split resonances in metamaterials
Identification Number:	doi:10.21979/N9/UMA5GK
Authoring Entity:	Thomas Tan Caiwei (Nanyang Technological University)
	Yogesh Kumar Srivastava (Nanyang Technological University)
	Manukumara Manjappa (Nanyang Technological University)
	Eric Plum (University of Southampton)
	Ranjan Singh (Nanyang Technological University)
Software used in Production:	Matlab
Software used in Production:	Origin
Grant Number:	NRF2016-NRF-ANR004
Grant Number:	EP/M009122/1
Distributor:	DR-NTU (Data)
Access Authority:	Thomas Tan Caiwei
Depositor:	Thomas Tan Caiwei
Date of Deposit:	2020-04-30
Holdings Information:	https://doi.org/10.21979/N9/UMA5GK
Study Scope
Keywords:	Physics, Physics, Metamaterial, Lattice mode, Strong coupling, High quality resonance
Abstract:	Strongly coupled metamaterial resonances typically undergo mode-splitting by which there is an exchange of energy between matter excitations and photons. Here, we report a strong coupling of the lattice mode with the structural eigen resonances of a split-ring metamaterial associated with mode-splitting and resonance line-narrowing that gives rise to high quality (Q) factor resonances. We demonstrate selective control of the resonance strength, line width and Q-factor of individual split-ring modes by tailoring the coupling of the fundamental lattice mode to each of the split-ring’s hybridized resonances. A three-coupled-oscillator model shows lattice-mediated strong coupling in the form of an anti-crossing behavior between the hybridized metamaterial resonances. Such schemes of strong coupling between the lattice and the split hybrid modes of the metamaterial unit cell offer an avenue to invoke high-Q resonances and strong field confinement which could find applications in designing ultrasensitive sensors, multiband narrow filters, and slow light devices.
Kind of Data:	process-produced data
Methodology and Processing
Sources Statement
Data Access
Other Study Description Materials
Related Publications
Citation
Identification Number:	10.1063/1.5026649
Bibliographic Citation:	Tan, T. C., Srivastava, Y. K., Manjappa, M., Plum, E., & Singh, R. (2018). Lattice induced strong coupling and line narrowing of split resonances in metamaterials. Applied Physics Letters, 112(20), 201111.
Citation
Identification Number:	10356/82963
Bibliographic Citation:	Tan, T. C., Srivastava, Y. K., Manjappa, M., Plum, E., & Singh, R. (2018). Lattice induced strong coupling and line narrowing of split resonances in metamaterials. Applied Physics Letters, 112(20), 201111.
File Description--f28076
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