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Main Authors: Ruiz, Javier, Jiménez-Díaz, Alberto, Egea-González, Isabel, Romeo, Ignacio, Kirby, Jon F., Audet, Pascal
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.06558
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author Ruiz, Javier
Jiménez-Díaz, Alberto
Egea-González, Isabel
Romeo, Ignacio
Kirby, Jon F.
Audet, Pascal
author_facet Ruiz, Javier
Jiménez-Díaz, Alberto
Egea-González, Isabel
Romeo, Ignacio
Kirby, Jon F.
Audet, Pascal
contents The absence of plate tectonics and the young surface age (0.3-1 billion years) of Venus have led to diverse geodynamic models for Venus. The energetics of the Venusian interior drive these models; however, the lack of direct constraints on surface heat flow hampers their quantitative assessment. Here we present a global heat flow model for Venus, as well as estimates of the total heat loss, obtained from an inversion of geophysical data, including lithospheric effective elastic thickness, crustal thickness, and radioactive heat production. Heat flow on Venus is lower and less geographically structured than on Earth, with an average of 31 mW m$^{-2}$, but with highs associated to rifts systems reaching values typical of active terrestrial areas. The obtained total heat loss is 11-17 TW, similar to estimates of the total radioactive heat production. Therefore, at present, Venus proportionally dissipates much less heat than Earth. Furthermore, the calculated crustal temperatures imply that crustal melting or eclogitization are not dominant processes in the Venusian crust.
format Preprint
id arxiv_https___arxiv_org_abs_2401_06558
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Heat loss and internal dynamics of Venus from lithosphere strength
Ruiz, Javier
Jiménez-Díaz, Alberto
Egea-González, Isabel
Romeo, Ignacio
Kirby, Jon F.
Audet, Pascal
Earth and Planetary Astrophysics
The absence of plate tectonics and the young surface age (0.3-1 billion years) of Venus have led to diverse geodynamic models for Venus. The energetics of the Venusian interior drive these models; however, the lack of direct constraints on surface heat flow hampers their quantitative assessment. Here we present a global heat flow model for Venus, as well as estimates of the total heat loss, obtained from an inversion of geophysical data, including lithospheric effective elastic thickness, crustal thickness, and radioactive heat production. Heat flow on Venus is lower and less geographically structured than on Earth, with an average of 31 mW m$^{-2}$, but with highs associated to rifts systems reaching values typical of active terrestrial areas. The obtained total heat loss is 11-17 TW, similar to estimates of the total radioactive heat production. Therefore, at present, Venus proportionally dissipates much less heat than Earth. Furthermore, the calculated crustal temperatures imply that crustal melting or eclogitization are not dominant processes in the Venusian crust.
title Heat loss and internal dynamics of Venus from lithosphere strength
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2401.06558