Litcius/Paper detail

Influence of ambient temperature on cavitation bubble dynamics

Shao-Cong Pei, A‐Man Zhang, Chang Liu, Tianyuan Zhang, Rui Han, Shuai Li

2025Journal of Fluid Mechanics12 citationsDOIOpen Access PDF

Abstract

We examine how ambient temperature $T$ (23–90 $^\circ \mathrm{C}$ ) alters the dynamics of spark-induced cavitation bubbles across a range of discharge energies. As $T$ rises, the collapse of an isolated spherical bubble weakens monotonically, as quantified by the Rayleigh collapse factor, minimum volume and maximum collapse velocity. When the bubble is generated near a rigid wall, the same thermal attenuation is reflected in reduced jet speed and diminished migration. Most notably, at $T \gtrsim 70\,^\circ \text{C}$ , we observe a previously unreported phenomenon: secondary cavitation nuclei appear adjacent to the primary bubble interface where the local pressure falls below the Blake threshold. The pressure reduction is produced by the over-expansion of the primary bubble itself, not by rarefaction waves as suggested in earlier work. Coalescence between these secondary nuclei and the parent bubble seeds pronounced surface wrinkles that intensify Rayleigh–Taylor instability and promote fission, providing an additional route for collapse strength attenuation. These findings clarify the inception mechanism of high-temperature cavitation and offer physical insight into erosion mitigation in heated liquids.

Topics & Concepts

BubbleCavitationMechanicsCoalescence (physics)InstabilityRarefaction (ecology)Ambient pressureMaterials scienceJet (fluid)Break-UpRayleigh scatteringVolume (thermodynamics)ImplosionAttenuationWakePhysicsBreaking waveDynamics (music)Rayleigh–Taylor instabilityImpact pressureShock waveLiquid bubbleThermalAir bubbleCavitation erosionPorosityFront (military)ErosionRange (aeronautics)Ultrasound and Cavitation PhenomenaCavitation Phenomena in PumpsUltrasound and Hyperthermia Applications