Research News 

Earthworm Calcite Granules that can be found in Loess-Sequences. Foto/©: Charlotte Prud’homme

A Loess-Seuquence at the Schwalbenberg site after ECG-sampling. Foto/©: Charlotte Prud’homme

Inconspicuous data source: Even many of today's earthworm excretions contain ECGs and thus detailed climate information. Foto/©: Olaf Jöris


deutsche Meldung


Ice Age temperatures and precipitation reconstructed from Earthworm granules

New method for determination of past climate data on land applied comparatively for the first time / Ice Age summers in Central Europe were at times warmer than previously known

Scientists from an international research project led by Johannes Gutenberg University Mainz (JGU) have applied a new method to reconstruct past climate. As they report in the current issue of Communications Earth & Environment, they have determined temperatures and precipitation during the last Ice Age, which peaked about 25,000 years ago, by analyzing earthworm granules. "The new method was discovered at Université Paris 1 Panthéon-Sorbonne and further developed at the Max Planck Institute for Chemistry," said Dr. Peter Fischer of JGU's Institute of Geography, who was the lead investigator of the TerraClime project funded by the German Research Foundation (DFG) in which the study is embedded. "In cooperation with other scientists, including researchers from the University of Lausanne and Römisch-Germanisches Zentralmuseum, we used the method to reconstruct the climate at Schwalbenberg near Remagen and Nußloch near Heidelberg." The two sites form well-developed last-glacial dust deposits. The so-called loess contains sequences dating from 45,000 to 22,000 years before present, in which the earthworm granules with up to about only 2.5 millimeters in size can be found throughout. These calcitic granules, technically known as Earthworm Calcite Granules (ECGs), are secreted daily by earthworms. Using the so-called radiocarbon method, which is based on the decay of the naturally occurring radioactive carbon isotope (14C), researchers can precisely determine their age. Additionally, by analyzing the ratios of stable oxygen and carbon isotopes in the ECGs, it is then possible to reconstruct how warm or how humid it was at the time of their formation.

Summer temperatures were higher than previously thought and humidity was significantly reduced

"Analysis of the data obtained from the ECGs shows that from 45,000 to 22,000 years before present it was much drier in Central Europe than it is today, with up to 70 percent less humidity," said Dr. Charlotte Prud'homme from the University of Lausanne, the study's lead author. "This allows us for the first time to quantify previous findings about this period." The novelty in these investigations on ECGs is that summer temperatures at the time were significantly higher than previously thought. "Although summers during the cold maximum of the last glacial were about four to eleven degrees Celsius colder than today, they were only one to four degrees below the values of short milder climatic phases that occurred during the last glacial," explained Fischer. "Given these summer temperatures, we cannot exclude that Ice Age human populations may have made a seasonal living in Central Europe during the cold maximum, at a time for which it is generally assumed that humans could not survive here," added Dr. Olaf Jöris of Römisch-Germanisches-Zentralmuseum, who was also involved in the study.

"Until now, reconstructions of Ice Age climate have been mainly based on the analyses of microorganisms in deep-sea deposits," stated Fischer. For the continents, corresponding comprehensive data have been lacking so far, which can be changed with the new method: "Since ECGs can be found in many loess sequences, temperatures and precipitation of the past can now be determined on land over a large area. One main aim is to build a database that can be used to precisely quantify past climate changes on land and to identify force feedback mechanisms. Incorporating land-based climate data will increase the database and contribute to improve existing climate modelling and thus provide valuable insights for future climate change."

The German Research Foundation funded the TerraClime project including the ECG dating with around EUR 400,000.

Publication:

C. Prud'homme et al., Millennial-timescale quantitative estimates of climate dynamics in central Europe from earthworm calcite granules in loess deposits, Communications Earth & Environment 3: 267, 21 November 2022, DOI: 10.1038/s43247-022-00595-3
https://www.nature.com/articles/s43247-022-00595-3 

Related links:

Source

Press release of the Johannes Gutenberg-University, Mainz