Frequency tunable metamaterial designs using near field coupled SRR structures in the terahertz region

2011-12-01
Ekmekci, Evren
Strikwerda, A.c.
Fan, K.
Keiser, G.
Zhang, Xin
Sayan, Gönül
Averitt, Richard D.
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.

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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
Ekmekci, Evren; Strikwerda, A. C.; Fan, K.; Keiser, G.; Zhang, Xin; Turhan-Sayan, G.; Averitt, Richard D. (2011-05-06)
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)).
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. (2011-12-01)
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 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
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,” 2011, Accessed: 00, 2021. [Online]. Available: https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84893623417&origin=inward.