Strong Electronic Winds Blowing under Liquid Flows on Carbon Surfaces

Solid-liquid interfaces display a wealth of emerging phenomena at nanometer scales, which are at the root of their technological applications. While the interfacial structure and chemistry have been intensively explored, the potential coupling between liquid flows and the solid's electronic degrees of freedom has been broadly overlooked up till now. Despite several reports of electronic currents induced by liquids flowing in various carbon nanostructures, the mechanisms at stake remain controversial. Here, we unveil the molecular mechanisms of interfacial liquid-electron coupling by investigating flow-induced current generation at the nanoscale. We use a tuning fork atomic force microscope to deposit and displace a micrometric liquid droplet on a multilayer graphene sample, and observe an electronic current induced by the droplet displacement. The measured current is several orders of magnitude larger than previously reported for water on carbon, and further boosted by the presence of surface wrinkles on the carbon surface. Our results point to a peculiar momentum transfer mechanism between the fluid molecules and graphene charge carriers, mediated mainly by the solid's phonon excitations. These findings open new avenues for active control of nanoscale liquid flows through the solid walls' electronic degrees of freedom.

Automated summary

Solid-liquid interfaces exhibit emerging phenomena at nanometer scales, which are crucial for their technological applications. However, the coupling between liquid flows and the solid's electronic degrees of freedom has been largely overlooked. In this study, we investigate the molecular mechanisms of interfacial liquid-electron coupling and reveal flow-induced current generation at the nanoscale. Our findings demonstrate a momentum transfer mechanism between fluid molecules and graphene charge carriers, mediated by the solid's phonon excitations, and open up new possibilities for controlling nanoscale liquid flows through the solid walls' electronic degrees of freedom.