A multi-phase thermo-mechanical model for rock-ice avalanche

Autor: Pudasaini, Shiva P.
Rok vydání: 2024
Předmět:
Druh dokumentu: Working Paper
Popis: We propose a novel physically-based multi-phase thermo-mechanical model for rock-ice avalanche. The model is built on a multi-phase mass flow model and extends a two-phase rock-ice avalanche model. It considers rock, ice and fluid; includes the mechanism of ice-melting and a rigorously derived dynamically changing general temperature equation for avalanching bulk mass, the first of its kind. It explains advection-diffusion of heat including the heat exchange across the rock-ice avalanche body, basal heat conduction, production and loss of heat due to frictional shearing and changing temperature, a general formulation of the ice melting rate and enhancement of temperature due to basal entrainment. The temperature equation includes a composite term containing coupled dynamics: rate of change of thermal conductivity and temperature. Ice melt intensity determines these rates as mixture conductivity evolves, characterizing distinctive thermo-mechanical processes. The model highlights essential aspects of rock-ice avalanches. Lateral heat productions play an important role in temperature evolution. Fast moving avalanches produce higher amount of heat. Fast ice melting results in substantial change in temperature. We formally derive the melting efficiency dependent general fluid production rate. The model includes internal mass and momentum exchanges between the phases and mass and momentum productions due to entrainment. The latter significantly changes the state of temperature; yet, the former exclusively characterizes rock-ice avalanche. Temperature changes are rapid when heat entrainment across the avalanche boundary is substantial. It also applies to basal heat conduction. A strong coupling exists between phase mass and momentum balances and the temperature equation. The new model offers the first-ever complete dynamical solution for simulating rock-ice avalanche with changing temperature.
Comment: Enhanced text and model equations
Databáze: arXiv