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Plasmonic nanoring fabrication tuned to pitch: Efficient, deterministic, and large scale realization of ultra-small gaps for next generation plasmonic devices

Applied Physics Letters (2014) 105(14)
DOI: 10.1063/1.4897497
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Abstract

A double-patterning process for scalable, efficient, and deterministic nanoring array fabrication is presented. It enables gaps and features below a size of 20nm. A writing time of 3min/cm2 makes this process extremely appealing for scientific and industrial applications. Numerical simulations are in agreement with experimentally measured optical spectra. Therefore, a platform and a design tool for upcoming next generation plasmonic devices like hybrid plasmonic quantum systems are delivered.

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CITATION STYLE

APA

Lehr, D., Alaee, R., Filter, R., Dietrich, K., Siefke, T., Rockstuhl, C., … Tünnermann, A. (2014). Plasmonic nanoring fabrication tuned to pitch: Efficient, deterministic, and large scale realization of ultra-small gaps for next generation plasmonic devices. Applied Physics Letters, 105(14). https://doi.org/10.1063/1.4897497

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