Sonoluminescence represents one of the most anomalous phenomena for orthodox acoustic physics, which attempts to model light emission during cavitation as a purely thermokinetic and chaotic event. In this work, applying the theoretical postulates of Quantum Diffusion (DQ-12), we demonstrate that this phenomenon is, in fact, a structured topological collapse. By defining water as a continuous fluid medium and the air bubble as a geometric asymmetry, we model the light flash as the unavoidable mechanism of thermodynamic relaxation in response to an extreme spatial friction peak. This approach provides a mechanistic explanation for the organized structure of the flash and validates the feasibility of using acoustically excited topological fluid dynamics for analog information processing.
VARCO et al. (Thu,) studied this question.