Tectonic degassing drove global temperature trends since 20 Ma

Herbert, T. D.; Dalton, C. A.; Liu, Zhonghui; Salazar, A. M.; Si, Weimin; Wilson, Douglas S.

doi:10.1126/science.abl4353

Cited by 49 publications

(43 citation statements)

References 84 publications

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“…Even though weathering of drylands could increase with increases in MAP from warming, their minimal weathering fluxes preclude large contributions to global weathering. Our estimate of 22 ± 3 kJ mol −1 is within the range of values inferred from inverse arguments based on recent global paleoclimate models (table S1C) [e.g., (12,63)]. Those low sensitivities were required within the paleoreconstruction models to reproduce reasonable atmospheric PCO 2 levels.…”

Section: Global Integrationsupporting

confidence: 83%

How temperature-dependent silicate weathering acts as Earth’s geological thermostat

Brantley

Shaughnessy

Lebedeva

et al. 2023

Science

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Earth’s climate may be stabilized over millennia by solubilization of atmospheric carbon dioxide (CO 2 ) as minerals weather, but the temperature sensitivity of this thermostat is poorly understood. We discovered that the temperature dependence of weathering expressed as an activation energy increases from laboratory to watershed as transport, clay precipitation, disaggregation, and fracturing increasingly couple to dissolution. A simple upscaling to the global system indicates that the temperature dependence decreases to ~22 kilojoules per mole because (i) the lack of runoff limits weathering and retains base metal cations on half the land surface and (ii) other landscapes are regolith-shielded and show little weathering response to temperature. By comparing weathering from laboratory to globe, we reconcile some aspects of kinetic and thermodynamic controls on CO 2 drawdown by natural or enhanced weathering.

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Section: Global Integrationsupporting

confidence: 83%

How temperature-dependent silicate weathering acts as Earth’s geological thermostat

Brantley

Shaughnessy

Lebedeva

et al. 2023

Science

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“…Finally, a deterministic climate on million-year timescales requires a lack of non- There is mounting evidence from the geologic past that icehouse-greenhouse transitions spanning millions of years are driven by the balance of weathering and volcanism (Caves et al, 2016;Dalton et al, 2022;Herbert et al, 2022;McKenzie et al, 2016;McKenzie & Jiang, 2019), rather than irreversible nudges across a critical threshold (Pohl et al, 2014;Stap et al, 2017). Our analysis strengthens the theoretical foundation underlying this empirical evidence for a deterministic long-term climate.…”

Section: Limitations Of Model Frameworksupporting

confidence: 66%

“…6C). For reference, volcanic degassing may have varied over the course of the Cenozoic by greater than 4×10 12 moles/yr (Berner, 2006;Caves et al, 2016;Herbert et al, 2022;Van Der Meer et al, 2014). This bistability window further collapses when we assume a lower climate inertia by requiring long-term stable states to be stable for all orbital configurations (stable fraction of 1).…”

Section: Climate Memorymentioning

confidence: 99%

“…The mechanisms behind these long-term cycles remain a first-order question in the Earth sciences. One set of theories posits that these cycles are driven by external forcings to the Earth system that modify the long-term carbon cycle, such as changes in long-term solid Earth degassing of CO 2 (Berner, 1991(Berner, , 2004(Berner, , 2006Herbert et al, 2022;Lee et al, 2013;McKenzie et al, 2016;McKenzie & Jiang, 2019;Van Der Meer et al, 2014) or internal processes such as changes in the efficiency of weathering reactions that sequester CO 2 (Caves et al, 2016;Caves Rugenstein et al, 2019;Krissansen-Totton & Catling, 2017;Kump & Arthur, 1997;Macdonald et al, 2019;Swanson-Hysell & Macdonald, 2017). Under these theories, the state of global climate is deterministic-it can be unambiguously determined if the external forcings and internal processes are known.…”

Section: Introductionmentioning

confidence: 99%

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Deterministic icehouse and greenhouse climates throughout Earth history

Kukla¹,

Lau²,

Ibarra³

et al. 2022

Preprint

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Some theories posit that icehouse (with polar ice sheets) and greenhouse (ice-free) states throughout Earth history are not deterministic, but bistable—both states may occur for the same level of radiative forcing. If correct, then the climate state that persists for millions of years can depend on which state already existed, giving the system a `memory’ effect. However, on these timescales the negative silicate weathering feedback in the long-term carbon cycle stabilizes global climate—a feedback which is missing from models that simulate a bistable system. Here, we test whether bistability persists on million-year timescales with a model that couples climate, weathering, and the long-term carbon cycle. We show that transitions between bistable states put the long-term carbon cycle out of balance and silicate weathering restores this balance, collapsing bistability. On million-year timescales any memory effect disappears, and the state of global climate is largely deterministic.

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“…However, implementation of enhanced ocean mixing (Lohmann et al, 2022), state-of-the-art parameterizations of cloud-aerosol interactions (Feng et al, 2019;Kiehl & Shields, 2013;Lunt et al, 2021; and improved representation of tidal mixing (Green & Huber, 2013;Lohmann, 2020) might improve the ability of models to simulate Miocene warmth and to reduce disagreement between modeled and reconstructed meridional temperature gradients. Model simulations with elevated CO 2 concentration, up to 1,100 ppm as recently reconstructed for the Early-Middle Miocene including the MCO by Herbert et al (2022), might also provide a better fit between climate simulations and reconstructed temperatures.…”

Section: Discussionmentioning

confidence: 96%

The Impact of Different Atmospheric CO₂ Concentrations on Large Scale Miocene Temperature Signatures

Hossain

Knorr

Jokat

et al. 2023

Paleoceanog and Paleoclimatol

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Proxy reconstructions show that the Miocene was a time period of global warmth. During this time, the configuration of continents, oceans and main orographies were only moderately different from those at present. With moderately higher atmospheric CO 2 and higher temperatures, the Miocene Climatic Optimum (MCO; ∼16.9-14.7 Ma) has been suggested as a partial analog for the Earth's future greenhouse climate (Steinthorsdottir et al., 2021).During the entire Miocene most proxy records reveal that atmospheric CO 2 was near or only moderately higher than preindustrial values (

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Tectonic degassing drove global temperature trends since 20 Ma

Cited by 49 publications

References 84 publications

How temperature-dependent silicate weathering acts as Earth’s geological thermostat

How temperature-dependent silicate weathering acts as Earth’s geological thermostat

Deterministic icehouse and greenhouse climates throughout Earth history

The Impact of Different Atmospheric CO₂ Concentrations on Large Scale Miocene Temperature Signatures

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Tectonic degassing drove global temperature trends since 20 Ma

Cited by 49 publications

References 84 publications

How temperature-dependent silicate weathering acts as Earth’s geological thermostat

How temperature-dependent silicate weathering acts as Earth’s geological thermostat

Deterministic icehouse and greenhouse climates throughout Earth history

The Impact of Different Atmospheric CO2 Concentrations on Large Scale Miocene Temperature Signatures

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Product

Resources

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The Impact of Different Atmospheric CO₂ Concentrations on Large Scale Miocene Temperature Signatures