Past global warming events offer insights into natural mechanisms that regulated Earth’s climate, such as rock weathering, which reduced atmospheric carbon dioxide. Today, enhancing rock weathering could help mitigate climate change, but its effectiveness depends on local geological conditions and the potential for clay formation, which can inhibit the process.
Could blending of crushed rock with arable soil lower global temperatures? Mainz University scientists study global warming events from 40 and 56 million years ago to find answers.
The Earth is getting hotter, and the effects have been increasingly evident this summer across the globe. Looking back in geological history, events of global warming are not uncommon. Around 56 million years ago, during the Paleocene–Eocene Thermal Maximum (PETM), temperatures rose by an average of 5 to 8 degrees CelsiusThe Celsius scale, also known as the centigrade scale, is a temperature scale named after the Swedish astronomer Anders Celsius. In the Celsius scale, 0 °C is the freezing point of water and 100 °C is the boiling point of water at 1 atm pressure.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Celsius.
This increase in temperature was likely caused by heightened volcanic activity and the consequent release of vast amounts of carbon dioxide into the atmosphere. These elevated temperatures persisted for approximately 200,000 years.
Back in 2021, Professor Philip Pogge von Strandmann of Johannes Gutenberg University Mainz (JGU) had already investigated the effect that eventually led to global cooling and climatic recovery after the PETM warming.
In short: Rainwater combined with the atmospheric carbon dioxide, resulting in carbonic acidAny substance that when dissolved in water, gives a pH less than 7.0, or donates a hydrogen ion.” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>acid that caused enhanced weathering of rock, thus releasing calcium and magnesium. Rivers then transported the calcium, magnesium, and carbonic acid into the oceans where the calcium, magnesium – and also the carbon dioxide – came together to form insoluble limestone.
“In other words, there is a feedback effect that helps control the climate. High temperatures accelerate the chemical rock weathering process, reducing the levels of carbon dioxide in the atmosphere, allowing the climate to recover,” said Pogge von Strandmann.
Climate required twice as long to regenerate 40 million years ago
Climate warming occurred again 16 million years after the PETM during the Middle Eocene Climatic Optimum or MECO. Although volcanic activity resulted in the discharge of roughly the same amounts of carbon dioxide into the atmosphere as during the PETM, it took far longer for the climate to restabilize.
The warming effect lasted for an immense 400,000 years, twice as long as in the PETM. Why was recovery so slow during that period?
The graphs illustrate changes to climate, carbon dioxide concentrations, and clay formation during the MECO. Credit: Alexander Krause
In searching for an answer, Pogge von Strandmann and co-authors, including first author Alex Krause, began analyzing 40-million-year-old oceanic carbonates and clay minerals to compare the results with those for similar 56-million-year-old examples. “Just as during the PETM, there was also intensified weathering and erosion in the MECO.
However, there was far less exposed rock on the Earth’s surface 40 million years ago. Instead, the Earth was extensively covered by a global rainforest the soil of which largely consisted of clay minerals,” explained the researcher. In contrast with rock, clay does not weather; in fact, it is actually the product of weathering. “So despite the high temperatures, the widespread clay soil prevented rocks from being effectively weathered, a process known as soil shielding,” the geoscientist pointed out.
Enhanced weathering for climate protection
How can we use this knowledge in today’s world? “We study paleoclimates to determine whether and how we can positively influence our present climate. One option might be to boost the chemical weathering of rock. To help achieve this, we could plow finely crushed rock into our fields,” said Pogge von Strandmann.
The fine-grained particles of rock would erode rapidly, resulting in the binding of atmospheric carbon dioxide, thus enabling the climate to recuperate. Negative emissions technologies (NETs) such as this involving the absorption of carbon dioxide are the subjects of intense research across the globe. At the same time, however, if the weathering results in the formation of clay, the effects of the process would be significantly less efficient, as Pogge von Strandmann has discovered.
Clay retains the calcium and magnesium that would otherwise be delivered to the ocean. The carbon dioxide would continue to flow into the oceans, but it would not be bound there and would be able to escape back into the atmosphere. In this case, the weathering effect would have next to no influence on the climate.
If the rock particles fully dissolve as a result of weathering, the enhanced weathering concept would turn out to be 100 percent efficient. However, if all the weathered materials were turned into clay, this would in its turn completely nullify the effect.
In reality, the actual outcome would probably be somewhere between the two extremes: While there was enhanced erosion of rock in the PETM so that the climate normalized more rapidly, clay formation was predominant during the MECO. The extent to which the crushed rock dissolves and how much of it is preserved as clay depends on a range of local factors, such as the globally pre-existing levels of clay and rock. So in order to establish whether the process of enhanced weathering is a viable approach, it would first be necessary to find out how much clay is formed during the weathering process at each potential location.
Reference: “Enhanced clay formation key in sustaining the Middle Eocene Climatic Optimum” by Alexander J. Krause, Appy Sluijs, Robin van der Ploeg, Timothy M. Lenton and Philip A. E. Pogge von Strandmann, 31 July 2023, Nature Geoscience<span class="st"> Nature Geoscience is a monthly peer-reviewed scientific journal published by the Nature Publishing Group that covers all aspects of the Earth sciences, including theoretical research, modeling, and fieldwork. Other related work is also published in fields that include atmospheric sciences, geology, geophysics, climatology, oceanography, paleontology, and space science. </span><span class="st">It was established in January 2008.
</span>” data-gt-translate-attributes=”[{“attribute”:”data-cmtooltip”, “format”:”html”}]”>Nature Geoscience.
DOI: 10.1038/s41561-023-01234-y
Also involved in the project were researchers at University College London and the University of Essex in the UK as well as Utrecht University in the Netherlands.
Source: SciTechDaily
