Interfacial tension-driven relaxation of magma foam: An experimental study

Abstract

To improve our understanding of permeability evolution of magmas in a shallow volcanic conduit, we experimentally investigated the interfacial tension-driven microstructural relaxation of foamed magma. By heating pumice cubes at temperatures of 800-1000°C and ≤6 MPa vapor pressure, we simulated magmas in interexplosion periods of vulcanian activity, including magmatic clasts welding within a shallow conduit. Outlines and internal pore microstructures of run products relaxed significantly in 3-5 and 30 min at 1000 and 900°C, respectively. In addition, self-contraction was caused by the expulsion of pores connected to sample surfaces. As a result of self-contraction, the porosity of 3 mm side pumice cubes decreased from 72 to 15% in 8 h at 900°C. For larger starting materials (9 mm side pumice cubes), multiple-contraction units formed melt globs, which promoted the formation of connected pores with concave outward shapes between globs. In contrast to the interbubble network, such pores are expected to maintain high permeability on a macroscopic scale; therefore, magma outgassing could be facilitated. These interglob pores were pinched off due to gravitational compaction after 8-32 h at 1000°C. The rapid and drastic changes in pore microstructures via relaxation, contraction, and compaction processes may be responsible for vent plugging during vulcanian explosion cycles.