Controlling Subnanometer Gaps in Plasmonic Dimers Using Graphene

Jan Mertens; Anna Eiden; Daniel O. Sigle; Fumin Huang; Antonio Lombardo; Z. Sun; Ravi S. Sundaram; A. Colli; Christos Tserkezis; Javier Aizpurua; Silvia Milana; Andrea C. Ferrari; Jeremy J. Baumberg

doi:10.1021/nl4018463

Controlling Subnanometer Gaps in Plasmonic Dimers Using Graphene

Jan Mertens(University of Cambridge), Anna Eiden(University of Cambridge), Daniel O. Sigle(University of Cambridge), Fumin Huang(University of Cambridge), Antonio Lombardo(University of Cambridge), Z. Sun(University of Cambridge), Ravi S. Sundaram(University of Cambridge), A. Colli(Nokia (United Kingdom)), Christos Tserkezis(Donostia International Physics Center), Javier Aizpurua(Donostia International Physics Center), Silvia Milana(University of Cambridge), Andrea C. Ferrari(University of Cambridge), Jeremy J. Baumberg(University of Cambridge)

Nano Letters

September 24, 2013

10.1021/nl4018463

Cited by 230Open Access

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Abstract

Graphene is used as the thinnest possible spacer between gold nanoparticles and a gold substrate. This creates a robust, repeatable, and stable subnanometer gap for massive plasmonic field enhancements. White light spectroscopy of single 80 nm gold nanoparticles reveals plasmonic coupling between the particle and its image within the gold substrate. While for a single graphene layer, spectral doublets from coupled dimer modes are observed shifted into the near-infrared, these disappear for increasing numbers of layers. These doublets arise from charger-transfer-sensitive gap plasmons, allowing optical measurement to access out-of-plane conductivity in such layered systems. Gating the graphene can thus directly produce plasmon tuning.

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