SERS Substrates Formed by Gold Nanorods Deposited on Colloidal Silica Films

Overview

Journal Nanoscale Res Lett

Publisher Springer

Specialty Biotechnology

Date 2013 May 24

PMID 23697339

Citations 3

Authors

Mikhail Yu Tsvetkov

Boris N Khlebtsov

Vitaly A Khanadeev

Victor N Bagratashvili

Peter S Timashev

Mikhail I Samoylovich

Nikolai G Khlebtsov

Affiliations

Soon will be listed here.

Abstract

We describe a new approach to the fabrication of surface-enhanced Raman scattering (SERS) substrates using gold nanorod (GNR) nanopowders to prepare concentrated GNR sols, followed by their deposition on an opal-like photonic crystal (OPC) film formed on a silicon wafer. For comparative experiments, we also prepared GNR assemblies on plain silicon wafers. GNR-OPC substrates combine the increased specific surface, owing to the multilayer silicon nanosphere structure, and various spatial GNR configurations, including those with possible plasmonic hot spots. We demonstrate here the existence of the optimal OPC thickness and GNR deposition density for the maximal SERS effect. All other things being equal, the analytical integral SERS enhancement of the GNR-OPC substrates is higher than that of the thick, randomly oriented GNR assemblies on plain silicon wafers. Several ways to further optimize the strategy suggested are discussed.

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