The turbulent bubble break-up cascade. Part 1. Theoretical developments

TL;DR

This paper develops a theoretical framework for understanding the bubble break-up cascade in turbulent flows, showing that bubble size transfer is predominantly local and consistent with turbulence theories, aiding predictive modeling.

Contribution

It provides a theoretical basis for the bubble-mass cascade by extending population balance equations and quantifies the locality of bubble break-up in turbulent flows.

Findings

Bubble break-up transfer is strongly local with power-law decay of non-local effects.

Theoretical predictions align with experimental and simulation data.

Locality supports universal modeling of small-bubble turbulence.

Abstract

Breaking waves entrain gas beneath the surface. The wave-breaking process energizes turbulent fluctuations that break bubbles in quick succession to generate a wide range of bubble sizes. Understanding this generation mechanism paves the way towards the development of predictive models for large-scale maritime and climate simulations. Garrett et al. (2000) suggested that super-Hinze-scale turbulent breakup transfers entrained gas from large to small bubble sizes in the manner of a cascade. We provide a theoretical basis for this bubble-mass cascade by appealing to how energy is transferred from large to small scales in the energy cascade central to single-phase turbulence theories. A bubble break-up cascade requires that break-up events predominantly transfer bubble mass from a certain bubble size to a slightly smaller size on average. This property is called locality. In this paper, we analytically quantify locality by extending the population balance equation in conservative form to derive the bubble-mass transfer rate from large to small sizes. Using our proposed measures of locality, we show that scalings relevant to turbulent bubbly flows, including those postulated by Garrett et al. (2000) and observed in breaking-wave experiments and simulations, are consistent with a strongly local transfer rate, where the influence of non-local contributions decays in a power-law fashion. These theoretical predictions are confirmed using numerical simulations in Part 2, revealing key physical aspects of the bubble break-up cascade phenomenology. Locality supports the universality of turbulent small-bubble break-up, which simplifies the development of subgrid-scale models to predict oceanic small-bubble statistics of practical importance.