The oxidation of petrogenic organic carbon: a source of CO2 during transient warming events?
The oxidation of petrogenic organic carbon: a source of CO2 during transient warming events?
The terrestrial carbon cycle has long been discussed under a framework that focuses on inorganic carbon (i.e. the balance between solid Earth degassing and silicate weathering). Therefore, the role of organic carbon has remained poorly constrained in both the present and past. A recent study highlighted the importance of rock-derived “petrogenic” organic carbon (OCpetro), suggesting that the amount of CO2 released during the exhumation and mobilisation of OCpetro may be comparable to that from volcanism. To determine the response of OCpetro to future climate change, warming events in the geologic record can be investigated. For example, there are biomarker-based evidence for up to an order-of-magnitude increase in the burial of OCpetro in shallow-marine sediments dated to the Paleocene-Eocene thermal maximum (PETM; ∼56 Ma). However, estimates of the proportion of OCpetro lost via oxidation are unavailable due to the lack of suitable techniques.
Raman spectroscopy assesses differences in the crystallinity of OCpetro, allowing the distinction between graphitised and disordered carbon. Modern river systems have shown a shift towards a dominance of graphite downstream, as disordered carbon are more susceptible to oxidation. Here, we explore whether Raman spectroscopy can be used to reconstruct OCpetro oxidation in the past. During the PETM, there is an increase of graphite in the mid-Atlantic Coastal Plain, indicating enhanced OCpetro oxidation. This is consistent with signs of intensified physical erosion and enhanced OCpetro delivery. On the other hand, the distribution of graphitised carbon vs. disordered carbon (and biomarkers) do not change in the Arctic Ocean, implying spatial variability. This study demonstrates, for the first time, the utility of Raman spectroscopy as a novel tool to evaluate OCpetro oxidation in a geological context. Applying this approach to quantify oxidation rates require further ground truthing in settings with different degrees of weathering.
Hollingsworth, Emily
3c2fb70d-74ba-495a-910b-51220df30892
Sparkes, Robert
d9544d93-4908-45c4-b12d-4a90a21d63cc
Self-Trail, Jean
052b016f-5226-4940-84ea-a8d80850e8d7
Foster, Gavin
fbaa7255-7267-4443-a55e-e2a791213022
Inglis, Gordon
1651196d-916c-43cb-b5a0-9b3ecaf5d664
14 March 2026
Hollingsworth, Emily
3c2fb70d-74ba-495a-910b-51220df30892
Sparkes, Robert
d9544d93-4908-45c4-b12d-4a90a21d63cc
Self-Trail, Jean
052b016f-5226-4940-84ea-a8d80850e8d7
Foster, Gavin
fbaa7255-7267-4443-a55e-e2a791213022
Inglis, Gordon
1651196d-916c-43cb-b5a0-9b3ecaf5d664
Hollingsworth, Emily, Sparkes, Robert, Self-Trail, Jean, Foster, Gavin and Inglis, Gordon
(2026)
The oxidation of petrogenic organic carbon: a source of CO2 during transient warming events?
In EGU General Assembly 2026.
(doi:10.5194/egusphere-egu26-21846).
Record type:
Conference or Workshop Item
(Paper)
Abstract
The terrestrial carbon cycle has long been discussed under a framework that focuses on inorganic carbon (i.e. the balance between solid Earth degassing and silicate weathering). Therefore, the role of organic carbon has remained poorly constrained in both the present and past. A recent study highlighted the importance of rock-derived “petrogenic” organic carbon (OCpetro), suggesting that the amount of CO2 released during the exhumation and mobilisation of OCpetro may be comparable to that from volcanism. To determine the response of OCpetro to future climate change, warming events in the geologic record can be investigated. For example, there are biomarker-based evidence for up to an order-of-magnitude increase in the burial of OCpetro in shallow-marine sediments dated to the Paleocene-Eocene thermal maximum (PETM; ∼56 Ma). However, estimates of the proportion of OCpetro lost via oxidation are unavailable due to the lack of suitable techniques.
Raman spectroscopy assesses differences in the crystallinity of OCpetro, allowing the distinction between graphitised and disordered carbon. Modern river systems have shown a shift towards a dominance of graphite downstream, as disordered carbon are more susceptible to oxidation. Here, we explore whether Raman spectroscopy can be used to reconstruct OCpetro oxidation in the past. During the PETM, there is an increase of graphite in the mid-Atlantic Coastal Plain, indicating enhanced OCpetro oxidation. This is consistent with signs of intensified physical erosion and enhanced OCpetro delivery. On the other hand, the distribution of graphitised carbon vs. disordered carbon (and biomarkers) do not change in the Arctic Ocean, implying spatial variability. This study demonstrates, for the first time, the utility of Raman spectroscopy as a novel tool to evaluate OCpetro oxidation in a geological context. Applying this approach to quantify oxidation rates require further ground truthing in settings with different degrees of weathering.
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Published date: 14 March 2026
Venue - Dates:
EGU General Assembly, , Vienna, Austria, 2026-05-03 - 2026-05-08
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Local EPrints ID: 510761
URI: http://eprints.soton.ac.uk/id/eprint/510761
PURE UUID: 438da922-4c82-468f-ae6d-ecac1c7a58de
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Date deposited: 21 Apr 2026 16:46
Last modified: 22 Apr 2026 02:14
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Author:
Emily Hollingsworth
Author:
Robert Sparkes
Author:
Jean Self-Trail
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