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16.05.2025 10:46

Rising temperatures lead to unexpectedly rapid carbon release from soils

Ulrike Prange Pressestelle
MARUM - Zentrum für Marine Umweltwissenschaften an der Universität Bremen

How sensitively does organic carbon stored in soils react to changes in temperature and humidity? This question is central to a new study by researchers from MARUM – Center for Marine Environmental Sciences at the University of Bremen and from the Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research in Bremerhaven that was now published in Nature Communications.

Globally, soils store more than twice as much carbon as the atmosphere. Therefore, carbon uptake and release by soils constitutes a strong regulator of atmospheric concentrations of the greenhouse gas carbon dioxide (CO2). In the context of the ongoing anthropogenic climate change it is thus important to better understand the sensitivity of soil carbon, which is directly related to the release of CO2 from soils, under a changing climate, such as rising temperatures and/or variations in the hydrological cycle.

Studies have already highlighted the importance of permafrost regions, where rising temperatures lead to the release of carbon from previously frozen soils. However, large amounts of organic carbon are also stored in soils in subtropical and tropical regions. In these regions, it was previously unclear what the main factor for a change in the carbon turnover rate was. "Microbes that break down organic matter are generally more active under warm and humid conditions, so the carbon content in tropical soils responds very quickly to climatic changes. Some studies report a main influence of changing hydroclimatic conditions, while in others temperature plays the main role," explains first author Dr. Vera Meyer from MARUM.

Deposits provide a glimpse into the past
To shed more light on these large-scale processes, Meyer and her colleagues chose a rather unconventional approach. Instead of studying soils, they analyzed the age of land-derived organic matter that was transported from soils from the Nile to the Mediterranean and deposited near the river mouth. The Nile transports material from a huge catchment area in the subtropical to tropical regions of north-east Africa to the eastern Mediterranean. The samples for the study come from a coastal marine sediment core in which the age evidence of many thousands of years has been deposited. Such sediment cores therefore allow a much longer look back into times in the Earth's history when the climate was significantly different from today and changed considerably. "The age of the organic material delivered by the Nile essentially depends on two factors: how long it was in the soils, and how long it took to be transported in the river. The advantage of our approach is that long time scales can be investigated, in this case the last 18,000 years since the last ice age," says Dr. Enno Schefuß, also from MARUM.

The results surprised the researchers and showed something unexpected: the ages of the land carbon changed only slightly with changes in precipitation and the associated changes in runoff, but reacted strongly to changes in temperature. In addition, the change in ages due to the temperature increase after the last ice age was significantly greater than expected. This means that the post-glacial warming drastically accelerated the decomposition of organic matter by microorganisms in soils and caused a much stronger outgassing of CO2 from (sub-)tropical soils than predicted by carbon cycle models. Co-author Dr. Peter Köhler from AWI Bremerhaven says: “The fact that the models underestimate carbon release from soils so strongly shows us that we need to revise the sensitivity of soil carbon in our models.”

However, this effect not only contributed to the increase in atmospheric CO2 concentration at the end of the last ice age, but also has far-reaching consequences for the future: the carbon turnover in soils will accelerate with further global warming and could further increase the atmospheric CO2 concentration via a previously underestimated feedback.

The study was funded as part of the Cluster of Excellence “Ocean Floor – Earth's Uncharted Interface”. The cluster is based at MARUM at the University of Bremen. The aim of these comprehensive investigations is to decipher the fate of carbon from various sources in the marine environment.

MARUM produces fundamental scientific knowledge about the role of the ocean and the ocean floor in the total Earth system. The dynamics of the ocean and the ocean floor significantly impact the entire Earth system through the interaction of geological, physical, biological and chemical processes. These influence both the climate and the global carbon cycle, and create unique biological systems. MARUM is committed to fundamental and unbiased research in the interests of society and the marine environment, and in accordance with the Sustainable Development Goals of the United Nations. It publishes its quality-assured scientific data and makes it publicly available. MARUM informs the public about new discoveries in the marine environment and provides practical knowledge through its dialogue with society. MARUM cooperates with commercial and industrial partners in accordance with its goal of protecting the marine environment.

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Wissenschaftliche Ansprechpartner:

Dr. Vera D. Meyer
MARUM – Center for Marine Environmental Sciences, University of Bremen
Email: vmeyer@marum-alumni.de
Dr. Enno Schefuß
MARUM – Center for Marine Environmental Sciences, University of Bremen
Phone: 0421 – 21865526
Email: eschefuss@marum.de
Prof. Gesine Mollenhauer
Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research Bremerhaven
Email: Gesine.Mollenhauer@awi.de
Dr. Peter Köhler
Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research, Bremerhaven
Email: Peter.Koehler@awi.de

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Originalpublikation:

Vera D. Meyer, Peter Köhler, Nadine T. Smit, Julius S. Lipp, Binging Wei, Gesine Mollenhauer, Enno Schefuß: Dominant Control of Temperature on (sub-)tropical soil carbon turnover. Nature Communications 2025. DOI: https://doi.org/10.1038/s41467-025-59013-9

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Dr. Vera Meyer and Dr. Enno Schefuß discuss the isolation of organic compounds at the preparative ga ...
Volker Diekamp
Photo: MARUM – Center for Marine Environmental Sciences, University of Bremen; V. Diekamp

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Merkmale dieser Pressemitteilung:
Journalisten
Biologie, Chemie, Geowissenschaften, Meer / Klima
überregional
Forschungsergebnisse, Wissenschaftliche Publikationen
Englisch

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