Your search keyword '"Lauderdale, Jonathan"' showing total 3 results

1. Carbon isotope budget indicates biological disequilibrium dominated ocean carbon storage at the Last Glacial Maximum.

Author

Omta, Anne Willem, Follett, Christopher L., Lauderdale, Jonathan M., and Ferrari, Raffaele

Subjects

LAST Glacial Maximum, ATMOSPHERIC carbon dioxide, GLACIAL climates, CARBON isotopes, ISOTOPIC signatures

Abstract

Understanding the causes of the ~90 ppmv atmospheric CO2 swings between glacial and interglacial climates is an important open challenge in paleoclimate research. Although the regularity of the glacial-interglacial cycles hints at a single driving mechanism, Earth System models require many independent physical and biological processes to explain the full observed CO2 signal. Here we show that biologically sequestered carbon in the ocean can explain an atmospheric CO2 change of 75 ± 40 ppmv, based on a mass balance calculation using published carbon isotopic measurements. An analysis of the carbon isotopic signatures of different water masses indicates similar regenerated carbon inventories at the Last Glacial Maximum and during the Holocene, requiring that the change in carbon storage was dominated by disequilibrium. We attribute the inferred change in carbon disequilibrium to expansion of sea-ice or change in the overturning circulation. Atmospheric CO2 was ~ 90 ppmv lower at the Last Glacial Maximum (LGM) than during the Holocene. Based on a carbon isotope budget, this study infers that at the LGM biological production pumped carbon into the deep ocean and sea ice kept it there. [ABSTRACT FROM AUTHOR]

Published

2024

2. Ocean iron cycle feedbacks decouple atmospheric CO2 from meridional overturning circulation changes.

Author

Lauderdale, Jonathan Maitland

Subjects

MERIDIONAL overturning circulation, ATMOSPHERIC tides, IRON, LIGANDS (Chemistry), CLIMATE change, IRON fertilizers

Abstract

The ocean's Meridional Overturning Circulation (MOC) brings carbon- and nutrient-rich deep waters to the surface around Antarctica. Limited by light and dissolved iron, photosynthetic microbes incompletely consume these nutrients, the extent of which governs the escape of inorganic carbon into the atmosphere. Changes in MOC upwelling may have regulated Southern Ocean outgassing, resulting in glacial-interglacial atmospheric CO2 oscillations. However, numerical models that explore this positive relationship do not typically include a feedback between biological activity and abundance of organic chelating ligands that control dissolved iron availability. Here, I show that incorporating a dynamic ligand parameterization inverts the modelled MOC-atmospheric CO2 relationship: reduced MOC nutrient upwelling decreases biological activity, resulting in scant ligand production, enhanced iron limitation, incomplete nutrient usage, and ocean carbon outgassing, and vice versa. This first-order response suggests iron cycle feedbacks may be a critical driver of the ocean's response to climate changes, independent of external iron supply. Dynamic ocean feedbacks between biological activity, chelating ligand levels, and dissolved iron availability may reverse carbon uptake or outgassing in response to changes in meridional overturning circulation, fundamentally impacting climate. [ABSTRACT FROM AUTHOR]

Published

2024

3. Ocean iron cycle feedbacks decouple atmospheric CO 2 from meridional overturning circulation changes.

Author

Lauderdale JM

Abstract

The ocean's Meridional Overturning Circulation (MOC) brings carbon- and nutrient-rich deep waters to the surface around Antarctica. Limited by light and dissolved iron, photosynthetic microbes incompletely consume these nutrients, the extent of which governs the escape of inorganic carbon into the atmosphere. Changes in MOC upwelling may have regulated Southern Ocean outgassing, resulting in glacial-interglacial atmospheric CO 2 oscillations. However, numerical models that explore this positive relationship do not typically include a feedback between biological activity and abundance of organic chelating ligands that control dissolved iron availability. Here, I show that incorporating a dynamic ligand parameterization inverts the modelled MOC-atmospheric CO 2 relationship: reduced MOC nutrient upwelling decreases biological activity, resulting in scant ligand production, enhanced iron limitation, incomplete nutrient usage, and ocean carbon outgassing, and vice versa. This first-order response suggests iron cycle feedbacks may be a critical driver of the ocean's response to climate changes, independent of external iron supply., (© 2024. The Author(s).)

Published

2024