Evolution of a protolunar disk in vapor/melt equilibrium

Autor: William R. Ward
Rok vydání: 2017
Předmět:
Zdroj: Journal of Geophysical Research: Planets. 122:342-357
ISSN: 2169-9097
DOI: 10.1002/2016je005198
Popis: A model of the viscous evolution of a two-phase, vapor/melt protolunar disk is described. Droplets condense from the vapor and "rain-out", forming a stratified structure with a mid-plane magma layer surrounded by a vapor reservoir. The magma layer is gravitationally unstable, but material interior to the Roche distance cannot fragment, and instead develops an effective viscosity. However, magma flowing across the Roche limit can fragment and accrete into moonlets, while magma spreading inward is accreted by Earth. As mass leaves the melt layer, it is replenished by vapor condensation, leading to a quasi steady-state (QSS). The layer's mass is maintained at ~14% of a lunar mass, and replaced every ~ 3 yrs. The vapor atmosphere steadily decreases, and once exhausted, the disk would cool below condensation temperature and spread as a time-dependent disk until it too is exhausted. The timescale of the QSS is regulated by the disk's ability to radiate all the released latent heat plus viscous dissipation energy to space at the photospheric temperature, i.e., ~2000 K for silicon phase-equilibrium. For the protolunar disk, latent heat dominates viscous heating, and the QSS for a ~2 lunar mass disk lasts for ~ 50 yrs. For comparison, a hypothetical water/steam disk orbiting an ice giant planet in which viscous heating dominates is also modeled. The photospheric temperature is closer to ~373 K, and the replacement time of the water layer is ~125 yrs. Finally, disks confined by external torques at either the planet-disk boundary or at its outer edge are also briefly examined.
Databáze: OpenAIRE