Abrupt changes in biomass burning during the last glacial period

Riddell-Young, Ben; Lee, James Edward; Brook, Edward J.; Schmitt, Jochen; Fischer, Hubertus; Bauska, Thomas K.; Menking, James A.; Iseli, René; Clark, Justin Reid

Abrupt changes in biomass burning during the last glacial period

Ben Riddell-Young (), James Edward Lee, Edward J. Brook, Jochen Schmitt, Hubertus Fischer, Thomas K. Bauska, James A. Menking, René Iseli and Justin Reid Clark
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Ben Riddell-Young: Oregon State University
James Edward Lee: Los Alamos National Laboratory
Edward J. Brook: Oregon State University
Jochen Schmitt: University of Bern
Hubertus Fischer: University of Bern
Thomas K. Bauska: British Antarctic Survey
James A. Menking: Commonwealth Scientific and Industrial Research Organization (CSIRO)
René Iseli: University of Fribourg
Justin Reid Clark: University of Colorado

Nature, 2025, vol. 637, issue 8044, 91-96

Abstract: Abstract Understanding the causes of past atmospheric methane (CH4) variability is important for characterizing the relationship between CH4, global climate and terrestrial biogeochemical cycling. Ice core records of atmospheric CH4 contain rapid variations linked to abrupt climate changes of the last glacial period known as Dansgaard–Oeschger (DO) events and Heinrich events (HE)1,2. The drivers of these CH4 variations remain unknown but can be constrained with ice core measurements of the stable isotopic composition of atmospheric CH4, which is sensitive to the strength of different isotopically distinguishable emission categories (microbial, pyrogenic and geologic)3–5. Here we present multi-decadal-scale measurements of δ13C–CH4 and δD–CH4 from the WAIS Divide and Talos Dome ice cores and identify abrupt 1‰ enrichments in δ13C–CH4 synchronous with HE CH4 pulses and 0.5‰ δ13C–CH4 enrichments synchronous with DO CH4 increases. δD–CH4 varied little across the abrupt CH4 changes. Using box models to interpret these isotopic shifts6 and assuming a constant δ13C–CH4 of microbial emissions, we propose that abrupt shifts in tropical rainfall associated with HEs and DO events enhanced 13C-enriched pyrogenic CH4 emissions, and by extension global wildfire extent, by 90–150%. Carbon cycle box modelling experiments7 suggest that the resulting released terrestrial carbon could have caused from one-third to all of the abrupt CO2 increases associated with HEs. These findings suggest that fire regimes and the terrestrial carbon cycle varied contemporaneously and substantially with past abrupt climate changes of the last glacial period.

Date: 2025
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DOI: 10.1038/s41586-024-08363-3

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