From the First to Subsequent Pulses: Evolution of Discharge inside a Preformed Bubble in Water

TL;DR

This study experimentally investigates how pulsed electrical discharges evolve inside a preformed water bubble, revealing the influence of pulse parameters and solution conductivity on discharge behavior and bubble stability.

Contribution

It provides new insights into the discharge evolution from the first to subsequent pulses inside preformed bubbles, highlighting the roles of pulse width, conductivity, and pulse history.

Findings

First pulse discharge is stochastic and corona-like.

Increasing pulse width transitions discharge to streamer mode.

Higher conductivity enhances discharge intensity and promotes bubble rupture.

Abstract

The evolution of pulsed discharge behavior inside a preformed air bubble in water from the first to subsequent pulses was experimentally investigated using a synchronized needle to bubble system. A positive nanosecond high-voltage pulsed power supply, together with a pulse valve and ICCD imaging, was employed to generate reproducible preformed bubbles and to record the corresponding discharge development with good temporal synchronization. The results show that, although the preformed bubbles exhibit good repeatability in size and morphology under identical conditions, the first-pulse discharge inside the bubble remains highly stochastic. The first discharge is predominantly corona-like and is not significantly affected by bubble size once the electrode is covered by the bubble. By varying the pulse width, the discharge inside the bubble was observed to evolve progressively from corona-like emission to streamer discharge, accompanied by increasing instability of the bubble interface. At sufficiently large pulse width and pulse number, bubble wrinkling and even rupture were induced. The effect of solution conductivity was also examined. Increasing conductivity significantly enhanced discharge intensity, enlarged the luminous region, and promoted streamer propagation along the inner bubble surface. At sufficiently high conductivity, the first pulse already produced strong discharge and rapid bubble rupture. In addition, the current amplitude and the energy dissipated per pulse increased with conductivity and pulse number. These results demonstrate that the discharge evolution inside a preformed bubble is jointly governed by pulse history, pulse width, and solution conductivity, and that residual effects from previous pulses play an important role in the transition from the first pulse to subsequent discharges.