Rayleigh-Taylor instability during impact cratering experiments

TL;DR

This study investigates the Rayleigh-Taylor instability during impact cratering, revealing how density contrast and impact dynamics influence mixing layers and planetary differentiation.

Contribution

It introduces a model linking impact parameters to Rayleigh-Taylor instability development and mixing, with experimental validation and geophysical implications.

Findings

Instability wavelength correlates with impact conditions.

Crater evolution explained by energy conservation and instability dynamics.

Implications for planetary core-mantle differentiation.

Abstract

When a liquid drop strikes a deep pool of a second liquid, an impact crater opens while the liquid of the drop decelerates and spreads on the surface of the crater. If the density of the drop is larger than the surrounding, the interface between the drop liquid layer and its surrounding becomes unstable, producing mushroom-shaped plumes growing radially outward. We interpret this instability as a spherical Rayleigh-Taylor instability associated with the deceleration of the interface between the drop and its surrounding, which significantly exceeds the ambient vertical gravity. We investigate experimentally how changing the density contrast and the impact Froude number affects the instability and the resulting mixing layer. Using backlighting and planar laser-induced fluorescence methods, the position of the air-liquid interface, the thickness of the mixing layer, and an estimate of the instability wavelength are obtained. First, the evolution of the mean crater radius is derived from an energy conservation model. The observed mixing layer dynamics is then explained by a model involving a competition between the geometrical expansion of the crater tending to decrease its thickness, and mixing produced by the Rayleigh-Taylor instability tending to increase its thickness. The estimated instability wavelength is finally compared to an approximate linear stability analysis of a radially accelerated fluid sphere into a less dense fluid. Mixing properties of this impact-related instability have geophysical implications regarding the differentiation of terrestrial planets, in particular by estimating the mass of magma ocean silicates that equilibrates with the metal core of the impacting planetesimals.