Issue 43, 2021

Optical field coupling in ZnO nanorods decorated with silver plasmonic nanoparticles

Abstract

Characterizing carrier redistribution due to optical field modulation in a plasmonic hot-electron/semiconductor junction can be used to raise the framework for harnessing the carrier decay of plasmonic metals in more efficient conversion systems. In this work we comprehensively studied the carrier redistribution mechanisms of a 1-dimensional (1D) metal-semiconductor Schottky architecture, holding the dual feature of a hot-electron plasmonic system and a simple metal/semiconductor junction. We obtained a strongly enhanced external quantum efficiency (EQE) of the plasmonic Ag decorated ZnO semiconductor in both the band-edge region of ZnO and the corresponding plasmonic absorption profile of the Ag NPs (visible region). Simultaneously, the insertion of an insulating Al2O3 intermediate layer between Ag NPs and ZnO resulted in a parallel distinction of the two main non-radiative carrier transfer mechanisms of plasmonic NPs, i.e. direct electron transfer (DET) and plasmonic induced resonance energy transfer (PIRET). The multi-wavelength transient pump–probe spectroscopy indicated the very fast plasmonic radiative transfer dynamics of the system in <500 fs below 389 nm. We demonstrate a 13% increase of photogenerated current in ZnO upon visible irradiation as a result of non-radiative plasmonic hot-electron injection from Ag NPs. Overall, our device encompasses several effective solutions for designing a plasmonic system featuring non-radiative electron–electron plasmonic dephasing and high photoconversion efficiencies.

Graphical abstract: Optical field coupling in ZnO nanorods decorated with silver plasmonic nanoparticles

Supplementary files

Article information

Article type
Paper
Submitted
29 Jun 2021
Accepted
17 Aug 2021
First published
19 Aug 2021
This article is Open Access
Creative Commons BY license

J. Mater. Chem. C, 2021,9, 15452-15462

Optical field coupling in ZnO nanorods decorated with silver plasmonic nanoparticles

M. Gilzad Kohan, S. You, A. Camellini, I. Concina, M. Zavelani Rossi and A. Vomiero, J. Mater. Chem. C, 2021, 9, 15452 DOI: 10.1039/D1TC03032A

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