Frequency Tunable Metamaterial Designs Using Near Field Coupled SRR Structures in the Terahertz Region

2011-05-06
Ekmekci, Evren
Strikwerda, A. C.
Fan, K.
Keiser, G.
Zhang, Xin
Turhan-Sayan, G.
Averitt, Richard D.
We present frequency tunable metamaterials at terahertz frequencies using broadside-coupled split ring resonators. Frequency tuning, arising from changes in near field coupling, is obtained by in-plane displacement between the SRR layers. A maximum frequency shift occurs for displacement of half a unit cell resulting in a shift of 663 GHz (51% of f(0)).

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Frequency tunable metamaterial designs using near field coupled SRR structures in the terahertz region
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We present frequency tunable metamaterials at terahertz frequencies using broadside-coupled split ring resonators (BC-SRRs). Frequency tuning, arising from changes in near field coupling, is obtained by in-plane displacement between the SRR layers. For electrical excitation, the resonance frequency continuously redshifts as a function of displacement. A maximum frequency shift occurs for displacement of half a unit cell resulting in a shift of 663 GHz (51% of f 0). We discuss the difference in the BC-SRR re...
Frequency tunable metamaterial designs using near field coupled SRR structures in the terahertz region
Ekmekci, Evren; Strikwerda, A.c.; Fan, K.; Keiser, G.; Zhang, Xin; Sayan, Gönül; Averitt, Richard D. (2011-12-01)
We present frequency tunable metamaterials at terahertz frequencies using broadsidecoupled split ring resonators. Frequency tuning, arising from changes in near field coupling, is obtained by in-plane displacement between the SRR layers. A maximum frequency shift occurs for displacement of half a unit cell resulting in a shift of 663 GHz (51% of f0). © OSA/CLEO 2011.
Frequency tunable metamaterial designs using near field coupled SRR structures in the terahertz region
Ekmekci, Evren; Strikwerda, A.c.; Fan, K.; Keiser, G.; Zhang, Xin; Sayan, Gönül; Averitt, Richard D. (2011-09-01)
We present frequency tunable metamaterials at terahertz frequencies using broadside-coupled split ring resonators. Frequency tuning, arising from changes in near field coupling, is obtained by in-plane displacement between the SRR layers. A maximum frequency shift occurs for displacement of half a unit cell resulting in a shift of 663 GHz (51% of f0). © 2011 OSA.
Frequency tunable metamaterial designs using near field coupled SRR structures in the terahertz region
Ekmekci, Evren; Strikwerda, A.c.; Fan, K.; Keiser, G.; Zhang, Xin; Sayan, Gönül; Averitt, Richard D. (2011-12-01)
We present frequency tunable metamaterials at terahertz frequencies using broadsidecoupled split ring resonators. Frequency tuning, arising from changes in near field coupling, is obtained by in-plane displacement between the SRR layers. A maximum frequency shift occurs for displacement of half a unit cell resulting in a shift of 663 GHz (51% of f0). © OSA/CLEO 2011.
Frequency Tunable Metamaterial Designs Using Near Field Coupled SRR Structures in the Terahertz Region
Ekmeki, Evren; Strikwerda, Andrew C.; Fan, Kebin; Keiser, George; Zhang, Xin; Sayan, Gönül; Averitt, Richard D. (2011-01-01)
We present frequency tunable metamaterials at terahertz frequencies using broadside-coupled split ring resonators (BC-SRRs). Frequency tuning, arising from changes in near field coupling, is obtained by in-plane displacement between the SRR layers. For electrical excitation, the resonance frequency continuously redshifts as a function of displacement. A maximum frequency shift occurs for displacement of half a unit cell resulting in a shift of 663 GHz (51% of f0). We discuss the difference in the BC-SRR res...
Citation Formats
E. Ekmekci et al., “Frequency Tunable Metamaterial Designs Using Near Field Coupled SRR Structures in the Terahertz Region,” pp. 0–0, 2011, Accessed: 00, 2020. [Online]. Available: https://hdl.handle.net/11511/68390.