Phanerozoic icehouse climates as the result of multiple solid-Earth cooling mechanisms

Andrew S. Merdith; Thomas M. Gernon; Pierre Maffre; Yannick Donnadieu; Yves Goddéris; Jack Longman; R Dietmar Müller; Benjamin J W Mills

doi:10.1126/sciadv.adm9798

Phanerozoic icehouse climates as the result of multiple solid-Earth cooling mechanisms

Andrew S. Merdith^*, Thomas M. Gernon, Pierre Maffre, Yannick Donnadieu, Yves Goddéris, Jack Longman, R Dietmar Müller, Benjamin J W Mills

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

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Abstract

The Phanerozoic climate has been interrupted by two long "icehouse" intervals, including the current icehouse of the last ~34 million years. While these cool intervals correspond to lower atmospheric CO2, it is unclear why CO2 levels fell, with hypotheses suggesting changes in CO2 degassing rates or modification of silicate weathering through changing continental lithology or paleogeography. Here, we construct an Earth System Model that integrates these proposed cooling mechanisms in detail. The model can reproduce the broad geologic record of ice cap expansion, allowing us to infer the primary drivers of long-term climate change. Our results indicate that recent icehouse climates required a combination of different cooling mechanisms acting simultaneously and were not driven by a single known process, potentially explaining why icehouses have been rarer than greenhouses over Earth history.

Original language	English
Article number	eadm9798
Number of pages	15
Journal	Science Advances
Volume	11
Issue number	7
Early online date	1 Feb 2025
DOIs	https://doi.org/10.1126/sciadv.adm9798
Publication status	Published - 14 Feb 2025

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Cite this

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T1 - Phanerozoic icehouse climates as the result of multiple solid-Earth cooling mechanisms

AU - Merdith, Andrew S.

AU - Gernon, Thomas M.

AU - Maffre, Pierre

AU - Donnadieu, Yannick

AU - Goddéris, Yves

AU - Longman, Jack

AU - Müller, R Dietmar

AU - Mills, Benjamin J W

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N2 - The Phanerozoic climate has been interrupted by two long "icehouse" intervals, including the current icehouse of the last ~34 million years. While these cool intervals correspond to lower atmospheric CO2, it is unclear why CO2 levels fell, with hypotheses suggesting changes in CO2 degassing rates or modification of silicate weathering through changing continental lithology or paleogeography. Here, we construct an Earth System Model that integrates these proposed cooling mechanisms in detail. The model can reproduce the broad geologic record of ice cap expansion, allowing us to infer the primary drivers of long-term climate change. Our results indicate that recent icehouse climates required a combination of different cooling mechanisms acting simultaneously and were not driven by a single known process, potentially explaining why icehouses have been rarer than greenhouses over Earth history.

AB - The Phanerozoic climate has been interrupted by two long "icehouse" intervals, including the current icehouse of the last ~34 million years. While these cool intervals correspond to lower atmospheric CO2, it is unclear why CO2 levels fell, with hypotheses suggesting changes in CO2 degassing rates or modification of silicate weathering through changing continental lithology or paleogeography. Here, we construct an Earth System Model that integrates these proposed cooling mechanisms in detail. The model can reproduce the broad geologic record of ice cap expansion, allowing us to infer the primary drivers of long-term climate change. Our results indicate that recent icehouse climates required a combination of different cooling mechanisms acting simultaneously and were not driven by a single known process, potentially explaining why icehouses have been rarer than greenhouses over Earth history.

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DO - 10.1126/sciadv.adm9798

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Phanerozoic icehouse climates as the result of multiple solid-Earth cooling mechanisms

Abstract

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