Exploding Taylor Cones

TL;DR

This paper investigates the formation of exploding Taylor cones caused by electrohydraulic discharge in a water-oil system, revealing how electric fields induce conical water interfaces and potential destructive explosions.

Contribution

It demonstrates the novel phenomenon of Taylor cone formation and explosion in a two-phase water-oil system under electrohydraulic discharge conditions.

Findings

Water/oil interface forms a Taylor cone before explosion.

Discharges cause conical deformation of the water interface.

Explosive destruction occurs under certain conditions.

Abstract

Application of a sufficiently strong electric field to an aqueous solution induces a phenomenon known as `electrohydraulic discharge'. The electric field causes the water to break down, generating either a corona (at lower field strengths) or a pulsed arc (at higher field strengths). The discharge typically results in a complex combination of physical processes (e.g., cavitation and light emission) and chemical reactions (e.g., generation of free radicals and nonthermal plasmas). The combination of physical and chemical processes tends to destroy any organic molecules present, and accordingly electrohydraulic discharges are currently being investigated as a potentially inexpensive and environmentally friendly means for purifying drinking water and removing contaminants from wastewater. Two types of electrode configurations have been the main focus of research to date: (i) a `one-phase' system with both electrodes immersed in water, or (ii) a `two-phase' system with one electrode in air and the other submerged in water. In this fluid dynamics video, we demonstrate the striking consequences of triggering an electrohydraulic discharge in a two-phase system comprised of water and a viscous, insulating oil. An air/water interface typically remains stationary until the discharge occurs; in contrast, the oil/water interface deforms into a conical shape (i.e., a Taylor cone) stretching from the water phase toward the oil-immersed electrode. The behavior after the cone contacts the electrode depends sensitively on the properties of the water and oil, and we demonstrate that, under appropriate conditions, destructive explosions occur.