Gas Mobility Patterns in Crystal Mush Analog Experiments
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Date
2024-12-19
Authors
Etheredge, MaKayla
Journal Title
Journal ISSN
Volume Title
Publisher
University of Oregon
Abstract
Volatile movement through crystal mush, which controls the efficiency of gas escape, is poorly understood. Previous studies using 2-D (Hele-Shaw) analog experiments show that the geometry (finger, fracture) and efficiency of gas escape is controlled by particle concentration. I extend this approach by adding photoelastic particles to track formation and destruction of force chains. 2-D analog (Hele-Shaw) experiments using solid particles (photoelastic disks), fluid (corn syrup), and gas (nitrogen) are used to quantify the role of varying injected gas flux (1000 cm3/s to 10000 cm3/s) on crystal and melt migration patterns. Experiments can be classified by gas geometry into fingering, transition and fracture regime; recorded pressure and light intensity provide a proxy for particle stresses caused by the gas flux rate.