Probing Electrified Liquid-Solid Interfaces with Scanning Electron Microscopy

ACS Appl Mater Interfaces. 2020 Dec 16;12(50):56650-56657. doi: 10.1021/acsami.0c19634. Epub 2020 Dec 2.

Abstract

Electrical double layers play a key role in a variety of electrochemical systems. The mean free path of secondary electrons in aqueous solutions is on the order of a nanometer, making them suitable for probing ultrathin electrical double layers at solid-liquid electrolyte interfaces. Employing graphene as an electron-transparent electrode in a two-electrode electrochemical system, we show that the secondary electron yield of the graphene-liquid interface depends on the ionic strength and concentration of the electrolyte and the applied bias at the remote counter electrode. These observations have been related to polarization-induced changes in the potential distribution within the electrical double layer and demonstrate the feasibility of using scanning electron microscopy to examine and map electrified liquid-solid interfaces.

Keywords: electrical double layer; electrified interfaces; electrochemistry; electrolyte; graphene electrode; liquid cell; polarization; scanning electron microscopy; secondary electron emission.