The Earth’s climate system is highly complex and its components, which include the ocean, atmosphere, and vegetation, are closely interlinked. Changes in individual parameters can have far-reaching effects on the entire system. To a certain extent, the individual components of the system are resilient and can absorb changes. Climate and Earth-system research, however, assume that there are various tipping points. If these are exceeded, the climate system can change its state within a short period of time. It is also presumed that tipping points in the climate system influence each other and can trigger chain reactions, or cascades.

Among the global tipping points are the Amazon rainforest and the large-scale Atlantic Meridional Overturning Circulation (AMOC). Further warming of the planet can lead to a significant weakening of the AMOC. This would slow down the conveyor belt that transports warm water to the northern regions, drastically changing the temperature distribution in the Atlantic. This would also have consequences for the Amazon region because the altered temperatures in the Atlantic would affect the atmospheric water cycle, and thus also the patterns and amounts of precipitation.

Analysis of Residual Pollen and Carbon

Exactly how the AMOC and the Amazon are interconnected as systems, and how marine circulation affects the Amazon region, have not yet been extensively researched. A group of researchers led by Dr. Thomas Akabane and Prof. Dr. Christiano Chiessi from the University of S?o Paulo has now analyzed changes in the vegetation of the Amazon region. With their international team, they have analyzed pollen and carbon residues representing the past 25,000 years from a marine sediment core taken from the mouth of the Amazon River.

This analysis provides the team with a detailed glimpse into the past of one of the most species-rich ecosystems on Earth. The data show how the vegetation, along with wet and dry periods, has changed during the climate events of the last ice age, called Heinrich Events, when the AMOC was drastically weakened. The researchers found, in particular, a dramatic decline in rainforest vegetation in the northern part of the Amazon region.

Close Connection Between Atlantic Circulation and the Amazon Ecosystem

“The study is the result of a long-term German-Brazilian cooperation project, which began in 2012 with a joint expedition of the MARIA S. MERIAN research vessel in the estuarine area of the Amazon. Our data show that the Amazon ecosystem was able to adapt in the past to changes in the patterns of precipitation that resulted from weakened Atlantic circulation. But a further weakening of the AMOC accompanied by an increase in deforestation could threaten the stability of this important global system,” says Dr. Stefan Mulitza of MARUM.

Further studies employing climate and vegetation models indicate that a weakening of the AMOC under present-day conditions would have a similar effect on Amazonian vegetation as it did during the last ice age. “The models have shown us that the AMOC does not have to collapse completely in order to affect the rainforest. The northern areas of the Amazon region are massively impacted by even moderate changes in the AMOC,” explains Dr. Matthias Prange of MARUM.

The results illustrate how complex the global system is. “Driving processes at high latitudes, such as the melting of Greenland ice, can have a substantial effect on the tropics. Such long-distance influences often have severe regional effects, very often for people who are only minimally responsible for causing climate change,” adds Prof. Dr. Gerrit Lohmann of AWI.

Original publication:

Thomas Akabane, Cristiano Chiessi, Marina Hirota, Ilham Bouimetarhan, Matthias Prange, Stefan Mulitza, Dailson Bertassoli Jr., Christoph H?ggi, Arie Staal, Gerrit Lohmann, Niklas Boers, Anne-Laure Daniau, Rafael Oliveira, Marília Campos, Xiaoxu Shi, Paulo De Oliveira: Weaker Atlantic overturning circulation increases the vulnerability of northern Amazon forests. Nature Geoscience 2024. DOI: 10.1038/s41561-024-01578-z
 

Participating Institutions:

Institute of Geosciences, University of S?o Paulo, Brazil
University of S?o Paulo, Brazil
Federal University of Santa Catarina, Brazil
UIZ-Ibn Zohr University, Agadir, Morocco
MARUM – Center for Marine Environmental Sciences, University of Bremen, Germany
ETH Zürich, Switzerland
Intercantonal Laboratory, Switzerland
Utrecht University, The Netherlands
AWI – Alfred Wegener Institute, Helmholz Centre for Polar and Marine Research, Germany
Technical University of Munich, Germany
Potsdam Institute for Climate Impact Research, Germany
University of Exeter, United Kingdom
University of Bordeaux, CNRS, Bordeaux INP, EPOC, France
University of Campinas, Brazil
Southern Marine Science and Engineering, Guangdong Laboratory (Zhuhai), China
Further Information:

Publication in Nature Geoscience: www.nature.com/articles/s41561-024-01578-z

Contact:

Dr. Matthias Prange
Geosystem Modelling
MARUM – Center for Marine Environmental Sciences and Faculty of Geosciences, University of Bremen
Email: mprangeprotect me ?!marumprotect me ?!.de

Dr. Stefan Mulitza
Paleoceanography
MARUM – Center for Marine Environmental Sciences and Faculty of Geosciences, University of Bremen
Email: smulitzaprotect me ?!marumprotect me ?!.de

Prof. Dr. Gerrit Lohmann
Paleoclimate Dynamics
MARUM – Center for Marine Environmental Sciences and Institute for Environmental Physics, University of Bremen
Alfred Wegener Institute, Helmholz Centre for Polar and Marine Research
Email: Gerrit.Lohmannprotect me ?!uni-bremenprotect me ?!.de

Dr. Thomas Akabane
Institute for Geosciences
University of S?o Paulo
Email: thomask.akabane@gmail.com

Prof. Dr. Christiano Chiessi
University of S?o Paulo
Email: chiessiprotect me ?!uspprotect me ?!.br