Ultra-Low Intensity Light-Driven Ionic Conductivity through a Plasmonic Nanopore

Abstract: Solid-state nanopore devices with plasmonic nanoantennas are powerful tools that allow for working with individual particles and molecules in solution as well as providing lightinduced control of ionic current flow through them. However, the ionic current flow manipulation by light still requires high power densities and, thus, results in the optical heating of the nanopore. Here, we solve this problem by using a 5 nm nanopore in the gap of a plasmonic bow-tie nanoantenna on a SiN x membrane irradiated by a br… Show more