Plasmonic Photochemistry as a Tool to Prepare Metallic Nanopores with   Controlled Diameter

German Lanzavecchia; Joel Kuttruff; Andrea Doricchi; Ali Douaki,; Kumaranchira Ramankutty Krishnadas; Isabel Garcia; Alba Viejo Rodr\'iguez,; Thomas W{\aa}gberg; Roman Krahne; Nicol\`o Maccaferri; and Denis Garoli

arXiv:2302.05982·physics.optics·May 24, 2023·1 cites

Plasmonic Photochemistry as a Tool to Prepare Metallic Nanopores with Controlled Diameter

German Lanzavecchia, Joel Kuttruff, Andrea Doricchi, Ali Douaki,, Kumaranchira Ramankutty Krishnadas, Isabel Garcia, Alba Viejo Rodr\'iguez,, Thomas W{\aa}gberg, Roman Krahne, Nicol\`o Maccaferri, and Denis Garoli

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TL;DR

This paper presents a novel plasmonic photocatalytic method to precisely fabricate metallic nanopores with tunable diameters down to 4 nanometers, enabling enhanced single-molecule detection and optical sensing applications.

Contribution

The study introduces a reproducible, large-scale approach to create tunable plasmonic nanopores using light-induced metal growth on dielectric nanotubes, with detailed insights from simulations.

Findings

01

Achieved nanopore diameters as small as 4 nm.

02

Demonstrated detection of dsDNA and nanoparticles.

03

Supported results with electromagnetic field simulations.

Abstract

We show that plasmonic solid-state nanopores with tunable hole diameter can be prepared via a photocatalytic effect resulting from the enhanced electromagnetic field inside a metallic ring prepared on top of a dielectric nanotube. Under white light illumination, the maximum field intensity in these nanorings induces a site selective metal nucleation and growth. We used this approach to prepare bare Au and bimetallic Au-Ag nanorings and demonstrate the reduction of the initial inner diameter of the nanopore down to 4 nanometers. This process can be applied over large arrays with good reproducibility and good control on the nanopore diameter. The tunability of the nanopore diameter can be used to enable optimized detection of single entities with different size, such as single nanoparticles or biomolecules. As proof-of-concept, we demonstrate the versatility of the platform to perform…

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Taxonomy

TopicsNanopore and Nanochannel Transport Studies · Anodic Oxide Films and Nanostructures · Nanoporous metals and alloys