The efficiency of plate tectonics and nonequilibrium dynamical evolution of planetary mantles

Consideration of the structure of dynamical equilibria in terrestrial planets using simplified descriptions of the relevant heat transport processes (rigid‐lid convection, plate tectonics, and heat pipe volcanism) reveals that if the efficiency of plate tectonic heat transport decreases at higher ma...

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Bibliographic Details
Published in:Geophysical research letters 2015-11, Vol.42 (21), p.9255-9260
Main Authors: Moore, W. B., Lenardic, A.
Format: Article
Language:English
Subjects:
Convection
Efficiency
Equilibrium
Evolution
Heat
Heat pipes
Heat transfer
Heat transport
High temperature
Meteorology
Planetary evolution
Planetary mantles
Planets
Plate tectonics
Tectonics
Temperature
Temperature effects
Terrestrial planets
Thermal evolution
Transport processes
Volcanic activity
Volcanism
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Summary:Consideration of the structure of dynamical equilibria in terrestrial planets using simplified descriptions of the relevant heat transport processes (rigid‐lid convection, plate tectonics, and heat pipe volcanism) reveals that if the efficiency of plate tectonic heat transport decreases at higher mantle temperature, then it cannot govern quasi‐equilibrium dynamical evolution, and the system is always evolving away from the plate tectonic regime. A planet on which plate tectonics is less efficient at higher temperature stays in heat pipe mode longer, spends less time undergoing plate tectonics, and has a low and ever‐decreasing Urey number during this phase. These conclusions are based solely on the structure of the equilibria in a system with less efficient plate tectonics in the past and are independent of the mechanisms leading to this behavior. Commonly used quasi‐equilibrium approaches to planetary thermal evolution are likely not valid for planets in which heat transport becomes less efficient at higher temperature. Key Points Parameterized thermal history models assume quasi‐equilibrium dynamical evolution Some plate tectonic models preclude quasi‐equilibrium dynamical evolution Multiple equilibria also require nonequilibrium approaches
ISSN:0094-8276
1944-8007
DOI:10.1002/2015GL065621