Rapid northern hemisphere ice sheet melting during the penultimate deglaciation

Stoll, Heather; Cacho, Isabel; Gasson, Edward; Śliwiński, Jakub; Kost, Oliver; Moreno, Ana; Iglesias, Miguel; Torner, Judit; Pérez‐Mejías, Carlos; Haghipour, Negar; Cheng, Hai

doi:10.1038/s41467-022-31619-3

Cited by 24 publications

(26 citation statements)

References 109 publications

(177 reference statements)

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“…Lechleitner et al (2021) show that an increase in soil gas pCO 2 is recorded in speleothem carbon isotope (δ 13 C spel ), which may retain information on soil respiration. Similarly, Stoll et al (2022), attribute trends in δ 13 C spel to soil gas and bedrock dissolution. They propose that higher temperatures increase vegetation productivity, thereby increasing soil CO 2 production, which leads to more negative δ 13 C in speleothems.…”

Section: Biotamentioning

confidence: 99%

“…Open and closed conditions are partly dictated by the water saturation state of the pore spaces, with complete water saturation producing closed conditions. Whether carbonate dissolution proceeds under open or closed conditions impacts both the rate of weathering processes (Buhmann & Dreybrodt, 1985a, 1985b) and trace element concentrations and isotopic compositions of dissolved species (Hendy, 1971; Stoll et al., 2022). A global study of spring water chemistry suggests that, on average, spring chemistry in carbonate regions is well‐explained by weathering under conditions that are open to soil CO 2 (Romero‐Mujalli et al., 2019).…”

Section: Exploring the Carbonate Endmembermentioning

confidence: 99%

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Carbonates in the Critical Zone

et al. 2023

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Earth's Critical Zone (CZ), the near‐surface layer where rock is weathered and landscapes co‐evolve with life, is profoundly influenced by the type of underlying bedrock. Previous studies employing the CZ framework have focused primarily on landscapes dominated by silicate rocks. However, carbonate rocks crop out on approximately 15% of Earth's ice‐free continental surface and provide important water resources and ecosystem services to ∼1.2 billion people. Unlike silicates, carbonate minerals weather congruently and have high solubilities and rapid dissolution kinetics, enabling the development of large, interconnected pore spaces and preferential flow paths that restructure the CZ. Here we review the state of knowledge of the carbonate CZ, exploring parameters that produce contrasts in the CZ in different carbonate settings and identifying important open questions about carbonate CZ processes. We introduce the concept of a carbonate‐silicate CZ spectrum and examine whether current conceptual models of the CZ, such as the conveyor model, can be applied to carbonate landscapes. We argue that, to advance beyond site‐specific understanding and develop a more general conceptual framework for the role of carbonates in the CZ, we need integrative studies spanning both the carbonate‐silicate spectrum and a range of carbonate settings.

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Section: Biotamentioning

confidence: 99%

Section: Exploring the Carbonate Endmembermentioning

confidence: 99%

Carbonates in the Critical Zone

et al. 2023

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“…Despite site to site heterogeneity, individual drips monitored over an 18 month period show very limited temporal variation in Mg/Sr ratios despite order of magnitude differences in drip rate, suggesting that in this cave, individual drips sample a relatively stable bedrock dissolution source. For most stalagmites, age models are published previously, including those for GAE, GAL, and GLO (Stoll et al, 2015;Stoll et al, 2013), GAR and GUL (Stoll et al, 2022).…”

Section: Analysis Of Fossil Stalagmitesmentioning

confidence: 99%

Distinguishing the vegetation and soil component of δ¹³C variation in speleothem records from degassing and prior calcite precipitation effects

Stoll

Day²,

Lechleitner³

et al. 2022

Preprint

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Abstract. The carbon isotopic signature inherited from soil/epikarst processes may be modified by degassing and prior calcite precipitation (PCP) before its imprint on speleothem calcite. Despite laboratory demonstration of PCP effects on carbon isotopes and increasingly sophisticated models of the governing processes, to date, there has been limited effort to deconvolve the dual PCP and soil/epikarst components in measured speleothem isotopic time series. In this contribution, we explore the feasibility, advantages, and disadvantages of using trace element ratios and δ44Ca to remove the overprinting effect of PCP on measured δ13C to infer the temporal variations in the initial δ13C of dripwater. In 8 examined stalagmites, the most widely utilized PCP indicators Mg/Ca and δ44Ca covary as expected. However, Sr/Ca does not show consistent relationships with δ44Ca so PCP is not universally the dominant control on Sr/Ca. From δ44Ca and Mg/Ca, our calculation of PCP as fCa, fraction of initial Ca remaining at the deposition of the stalagmite layer, yields multiple viable solutions depending on the assumed δ44Ca fractionation factor and inferred variation in DMg. Uncertainty in the effective fractionation of δ13C during degassing and precipitation contributes to uncertainty in the absolute value of estimated initial δ13C. Nonetheless, the trends in initial δ13C are less sensitive to these uncertainties. In coeval stalagmites from the same cave spanning 94 to 82 ka interval, trends in calculated initial δ13C are more similar than those in measured δ13C, and reveal a common positive anomaly initial δ13C during a stadial cooling event. During deglaciations, the trend of greater respiration rates and higher soil CO2 is captured in the calculated initial δ13C, despite the tendency of higher interglacial dripwater situation to favor more extensive PCP.

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“…Open and closed conditions are partly dictated by the water saturation state of the pore spaces, with complete water saturation producing closed conditions. Whether carbonate dissolution proceeds under open or closed conditions impacts both the rate of weathering processes (Buhmann & Dreybrodt, 1985a;Buhmann & Dreybrodt, 1985b) and trace element concentrations and isotopic compositions of dissolved species (Hendy, 1971;Stoll et al, 2022). A global study of spring water chemistry suggests that, on average, spring chemistry in carbonate regions is well-explained by weathering under conditions that are open to soil CO2 (Romero-Mujalli et al, 2019).…”

Section: Vadose Zone Gases and Open Vs Closed System Weatheringmentioning

confidence: 99%

“…Lechleitner et al (2021) show that an increase in soil gas pCO2 is recorded in speleothem carbon isotope (δ 13 Cspel), which may retain information on soil respiration. Similarly, Stoll et al (2022), attribute trends in δ 13 Cspel to soil gas and bedrock dissolution. They propose that higher temperatures increase vegetation productivity, thereby increasing soil CO2 production, which leads to more negative δ 13 C in speleothems.…”

Section: Biotamentioning

confidence: 99%

Carbonates in the Critical Zone

Covington

Martin

Toran

et al. 2022

Preprint

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Earth’s Critical Zone (CZ), the near-surface layer where rock is weathered and landscapes co-evolve with life, is profoundly influenced by the type of underlying bedrock. Previous studies employing the CZ framework have focused primarily on landscapes dominated by silicate rocks. However, carbonate rocks crop out on approximately 15% of Earth’s ice-free continental surface and provide important water resources and ecosystem services to ~1.2 billion people. Unlike silicates, carbonate minerals weather congruently and have high solubilities and rapid dissolution kinetics, enabling the development of large, interconnected pore spaces and preferential flow paths that restructure the CZ. Here we review the state of knowledge of the carbonate CZ, exploring parameters that produce contrasts in the CZ in different carbonate settings and identifying important open questions about carbonate CZ processes. We introduce the concept of a carbonate-silicate CZ spectrum and examine whether current conceptual models of the CZ, such as the conveyor model, can be applied to carbonate landscapes. We argue that, to advance beyond site-specific understanding and develop a more general conceptual framework for the role of carbonates in the CZ, we need integrative studies spanning both the carbonate-silicate spectrum and a range of carbonate settings.

show abstract

Rapid northern hemisphere ice sheet melting during the penultimate deglaciation

Cited by 24 publications

References 109 publications

Carbonates in the Critical Zone

Carbonates in the Critical Zone

Distinguishing the vegetation and soil component of δ¹³C variation in speleothem records from degassing and prior calcite precipitation effects

Carbonates in the Critical Zone

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Rapid northern hemisphere ice sheet melting during the penultimate deglaciation

Cited by 24 publications

References 109 publications

Carbonates in the Critical Zone

Carbonates in the Critical Zone

Distinguishing the vegetation and soil component of δ13C variation in speleothem records from degassing and prior calcite precipitation effects

Carbonates in the Critical Zone

Contact Info

Product

Resources

About

Distinguishing the vegetation and soil component of δ¹³C variation in speleothem records from degassing and prior calcite precipitation effects