How Air Entrapment in Hydrophobic Particle-Water-Air Mixtures Changes Post-Wildfire Mudflow Composition

TL;DR

This study reveals how air entrapment in hydrophobic particle-water-air mixtures significantly influences the structure and flow dynamics of post-wildfire mudflows, with implications for understanding their destructive behavior.

Contribution

It introduces a novel paradigm of air entrapment in post-wildfire mudflows and quantifies its effects on internal structure and flow properties.

Findings

Quantifies trapped air volume in mudflows.

Shows impact of particle size and gravity on structure.

Identifies hydrophobic particles' role in air retention.

Abstract

This paper shows critical new insights into how air entrapment affects the properties of rain-induced post-wildfire mudflows as a mixture of air bubbles, water, and hydrophobic sand. The idea of mudflows' internal structure containing trapped air bubbles is novel. Such mixtures can flow down slopes at incredible speeds, quickly blasting obstacles on the way and carrying large stone boulders and objects. The surficial soil particles turn hydrophobic due to the deposition of combusted organic matter during wildfires. Afterward, raindrops, splash, and erosion form devastating mudflows. We propose a new paradigm in which a significant amount of air remains entrapped in post-wildfire mudflow via hydrophobic particle-air attraction. Specific findings quantify the amount of air trapped within sand-water volumetric concentrations, the effect of intermixing energy, gravity, and sand particle size on outcome mudflow internal structure. As a result, little agglomerates of sand particles covering air bubbles characterize the mudflow mixture's internal structure.