Determining molecular orientation via single molecule SERS in a plasmonic nano-gap

Addison R. L. Marshall; Ali M. Adawi; Anker; Atwater; Ciracì; Crozier; Ding; Edwards; Etchegoin; Etchegoin; Fang; Francesco N. Viscomi; Garcı; Goulet; Günzler; He; Hill; Hong; Hu; Huang; Hudson; Itoh; Jamie Stokes; Jean-Sebastien G. Bouillard; Jin; Johannes Gierschner; John E. Proctor; Johnson; Kelly; Kirchain; Kneipp; Kneipp; Kneipp; Le Ru; Le Ru; Le Ru; Lee; Li; Lim; Lombardi; Maharjan; Maher; Maier; Moskovits; Nam; Nie; Pelton; Raether; Raman; Sigle; Taylor; Wang; Wang; Wang; Zhang; Zia

research

Determining molecular orientation via single molecule SERS in a plasmonic nano-gap

Authors: Addison R. L. Marshall
Ali M. Adawi
Anker
Atwater
Ciracì
Crozier
Ding
Edwards
Etchegoin
Etchegoin
Fang
Francesco N. Viscomi
Garcı
Goulet
Günzler
He
Hill
Hong
Hu
Huang
Hudson
Itoh
Jamie Stokes
Jean-Sebastien G. Bouillard
Jin
Johannes Gierschner
John E. Proctor
Johnson
Kelly
Kirchain
Kneipp
Kneipp
Kneipp
Le Ru
Le Ru
Le Ru
Lee
Li
Lim
Lombardi
Maharjan
Maher
Maier
Moskovits
Nam
Nie
Pelton
Raether
Raman
Sigle
Taylor
Wang
Wang
Wang
Zhang
Zia
Publication date: 1 January 2017
Publisher: 'Royal Society of Chemistry (RSC)'
Doi

Abstract

In this work, plasmonic nano-gaps consisting of a silver nanoparticle coupled to an extended silver film have been fully optimized for single molecule Surface-Enhanced Raman Scattering (SERS) spectroscopy. The SERS signal was found to be strongly dependent on the particle size and the molecule orientation with respect to the field inside the nano-gap. Using Finite Difference Time Domain (FDTD) simulations to complement the experimental measurements, the complex interplay between the excitation enhancement and the emission enhancement of the system as a function of particle size were highlighted. Additionally, in conjunction with Density Functional Theory (DFT), the well-defined field direction in the nano-gap enables to recover the orientation of individual molecules