Abstract
Our understanding of the long‐term evolution of the Earth system is based on the assumption that terrestrial weathering rates should respond to, and hence help regulate, atmospheric CO2 and climate. Increased terrestrial weathering requires increased carbonate accumulation in marine sediments, which in turn is expected to result in a long‐term deepening of the carbonate compensation depth (CCD). Here, we critically assess this long‐term relationship between climate and carbon cycling. We generate a record of marine deep‐sea carbonate abundance from selected late Paleocene through early Eocene time slices to reconstruct the position of the CCD. Although our data set allows for a modest CCD deepening, we find no statistically significant change in the CCD despite >3 °C global warming, highlighting the need for additional deep‐sea constraints on carbonate accumulation. Using an Earth system model, we show that the impact of warming and increased weathering on the CCD can be obscured by the opposing influences of ocean circulation patterns and sedimentary respiration of organic matter. From our data synthesis and modeling, we suggest that observations of warming, declining δ13C and a relatively stable CCD can be broadly reproduced by mid‐Paleogene increases in volcanic CO2 outgassing and weathering. However, remaining data‐model discrepancies hint at missing processes in our model, most likely involving the preservation and burial of organic carbon. Our finding of a decoupling between the CCD and global marine carbonate burial rates means that considerable care is needed in attempting to use the CCD to directly gauge global carbonate burial rates and hence weathering rates.
Highlights
On million year timescales, the partial pressure of atmospheric carbon dioxide and global temperature is widely assumed to be regulated primarily by global rates of silicate mineral weathering
From our data synthesis and modeling, we suggest that observations of warming, declining δ13C and a relatively stable carbonate compensation depth (CCD) can be broadly reproduced by mid‐Paleogene increases in volcanic CO2 outgassing and weathering
The most notable difference between our two time slices among deep sites occurs at Atlantic Integrated Ocean Drilling Program (IODP) Site U1403, where CaCO3 burial commenced in the earliest Eocene (NP10‐11 time slice; Expedition 342 Scientists, 2012; Figures 2 and 4)
Summary
The partial pressure of atmospheric carbon dioxide (pCO2) and global temperature is widely assumed to be regulated primarily by global rates of silicate mineral weathering. If this were not the case, even relatively small changes in volcanic outgassing would give rise to repeated and unbounded approximately million year timescale swings in pCO2 and climate Direct evidence for the link between pCO2, climate, and silicate weathering rates (as estimated by variations in strontium (Palmer & Elderfield, 1985) and lithium isotopes (Misra & Froelich, 2012) in marine carbonates) is currently ambiguous, with multiple possible interpretations of weathering proxy data sets. Constraining the role of silicate weathering is central to a full understanding of Earth's climate history
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