Issue 44, 2019

A nanofabricated plasmonic core–shell-nanoparticle library

Abstract

Three-layer core–shell-nanoparticle nanoarchitectures exhibit properties not achievable by single-element nanostructures alone and have great potential to enable rationally designed functionality. However, nanofabrication strategies for crafting core–shell-nanoparticle structure arrays on surfaces are widely lacking, despite the potential of basically unlimited material combinations. Here we present a nanofabrication approach that overcomes this limitation. Using it, we produce a library of nanoarchitectures composed of a metal core and an oxide/nitride shell that is decorated with few-nanometer-sized particles with widely different material combinations. This is enabled by resolving a long-standing challenge in this field, namely the ability to grow a shell layer around a nanofabricated core without prior removal of the lithographically patterned mask, and the possibility to subsequently grow smaller metal nanoparticles locally on the shell only in close proximity of the core. Focusing on the application of such nanoarchitectures in plasmonics, we show experimentally and by Finite-Difference Time-Domain (FDTD) simulations that these structures exhibit significant optical absorption enhancement in small metal nanoparticles grown on the few nanometer thin dielectric shell layer around a plasmonic core, and derive design rules to maximize the effect by the tailored combination of the core and shell materials. We predict that these structures will find application in plasmon-mediated catalysis and nanoplasmonic sensing and spectroscopy.

Graphical abstract: A nanofabricated plasmonic core–shell-nanoparticle library

Supplementary files

Article information

Article type
Paper
Submitted
19 Sep 2019
Accepted
21 Oct 2019
First published
21 Oct 2019

Nanoscale, 2019,11, 21207-21217

A nanofabricated plasmonic core–shell-nanoparticle library

A. Susarrey-Arce, K. M. Czajkowski, I. Darmadi, S. Nilsson, I. Tanyeli, S. Alekseeva, T. J. Antosiewicz and C. Langhammer, Nanoscale, 2019, 11, 21207 DOI: 10.1039/C9NR08097J

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