Scaling in global tidal dissipation of the Earth-Moon system

Abstract

The Moon migrated to r3.8×1010 cm over a characteristic time r/v=1010 Gyr by tidal interaction with the Earth's oceans at a present velocity of v=3.8 cm yr-1. We derive scaling of global dissipation that covers the entire history over the past 4.52 Gyr. Off-resonance tidal interactions at relatively short tidal periods in the past reveal the need for scaling with amplitude. The global properties of the complex spatio-temporal dynamics and dissipation in broad spectrum ocean waves is modeled by damping ε = h F/(2Q0), where h is the tidal wave amplitude, F is the tidal frequency, and Q0 is the Q-factor at the present time. It satisfies Q0 14 for consistency of migration time and age of the Moon consistent with observations for a near-resonance state today. It shows a startingly fast eviction of the Moon from an unstable near-synchronous orbit close to the Roche limit, probably in a protolunar disk. Rapid spin down of the Earth from an intial 30\% of break-up by the Moon favored early formation of a clement global climate. Our theory suggests moons may be similarly advantageous to potentially habitable exoplanets.