Laboratory experiments on the breakup of liquid metal diapirs

- Laboratory experiments on the fragmentation of liquid metal blobs falling through a viscous fluid.
- Variety of stable shapes for liquid metal drops.
- Intense internal dynamics within the cloud of liquid metal drops.
- Large distribution of drops sizes and stabilization of large drops by large viscosity ratio.
- Previous models of chemical/thermal equilibration only accurate in a statistical mean sense.

The validity of the iron rain scenario, i.e. the widely accepted model for the dynamics of iron sedimentation through a magma ocean during the latest stage of the Earth's accretion, is explored via a suite of laboratory experiments. Liquid gallium and mixtures of water and glycerol are used as analogs of the iron and the molten silicate respectively. This allows us to investigate the effects of the viscosity ratio between iron and silicate and to reproduce the relevant effects of surface tension on the fragmentation dynamics. While the classical iron rain scenario considers a population of purely spherical drops with a single characteristic radius that fall towards the bottom of the magma ocean at a unique velocity without any further change, our experiments exhibit a variety of stable shapes for liquid metal drops, a large distribution of sizes and velocities, and an intense internal dynamics within the cloud with the superimposition of further fragmentations and merging events. Our results demonstrate that rich and complex dynamics occur in models of molten metal diapir physics. Further, we hypothesize that the inclusion of such flows into state of the art thermochemical equilibration models will generate a similarly broad array of complex, and likely novel, behaviors.

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