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Tides on Other Earths: Implications for Exoplanet and Palaeo‐Tidal Simulations

B. W. Blackledge, Mattias Green, Rory Barnes, M. J. Way

2020Geophysical Research Letters24 citationsDOIOpen Access PDF

Abstract

Abstract A key controller of a planet's rotational evolution, and hence habitability, is tidal dissipation, which on Earth is dominated by the ocean tides. Because exoplanet or deep‐time Earth topographies are unknown, a statistical ensemble is used to constrain possible tidal dissipation rates on an Earth‐like planet. A dedicated tidal model is used together with 120 random continental configurations to simulate Earth's semidiurnal lunar tide. The results show a possible ocean tidal dissipation range spanning 3 orders of magnitude, between 2.3 GWto 1.9 TW (1 TW=10 12 W). When model resolution is considered, this compares well with theoretical limits derived for the energetics of Earth's present‐day deep ocean. Consequently, continents exert a fundamental control on tidal dissipation rates and we suggest that plate tectonics on a planet will induce a time‐varying dissipation analogous to Earth's. This will alter rotational periods over millions of years and further complicate the role of tides for planetary evolution.

Topics & Concepts

ExoplanetPlanetGeologyDissipationTidal accelerationTidal heatingTidal powerTidal ModelHabitabilityGeophysicsAstrobiologyOcean tideGeodesyPhysicsAstronomyOceanographyBiologyEcologyThermodynamicsAstro and Planetary ScienceGeology and Paleoclimatology ResearchGeomagnetism and Paleomagnetism Studies