Atmospheric tracing of Earth's evolution

HORIZON.1.1HORIZON-ERCID: 101041122
EC Contribution
€24,991
Consortium Size
2 orgs
Summary

Planetary atmospheres are fundamental reservoirs controlling the habitability of planets. The chemical and isotopic compositions of atmospheric constituents also hold clues on the geological evolution of the entire planetary body. Today, Earth's atmosphere contains about 80% dinitrogen and 20% dioxygen. Yet, there is no scientific consensus on how and why these two molecules emerged and persisted in the Earth's atmosphere. The interactions between the atmosphere and the continental crust also play a major role in controlling the bio-availability of nutrients and the composition of the atmosphere, and thus the climate. However, the evolution of the volume of continental crust over time is strongly debated. Project ATTRACTE will significantly improve our knowledge of the main drivers of atmospheric evolution over time. This will be achieved by going back in time and following the evolution of the composition of the Earth's atmosphere over geological eons. Analyses of gases contained in traditional and new paleo-atmospheric proxies, the post-impact hydrothermal minerals, will be carried out with innovative mass spectrometry techniques. The isotopic composition of paleo-atmospheric xenon will provide new constraints on the history of hydrogen escape for the Archean Earth. Coupled argon and nitrogen measurements will allow to determine, for the first time, the evolution of the partial pressure of atmospheric dinitrogen. Paleo-atmospheric data gathered during the project will be fed in numerical models of Earth's atmospheric and crustal evolution. This will allow to reconstruct how volatile elements have been exchanged between the silicate Earth and the atmosphere through time. Results gathered during project ATTRACTE will ultimately provide new datasets for climate studies of the ancient Earth but will also help building the scientific framework required to interpret future observations of exoplanetary atmospheres and to portray the geology of extrasolar planets.

Consortium (2)

Project Results (5)

Source: CORDIS, the EU research results database.

Publications (4)
Crash Chronicles: Relative contribution from comets and carbonaceous asteroids to Earth’s volatile budget in the context of an Early Instability
Icarus· 2024DOI
Sarah Joiret, Sean N. Raymond, Guillaume Avice, Matthew S. Clement
Nitrogen sequestration in the core at megabar pressure and implications for terrestrial accretion
Geochimica et Cosmochimica Acta· 2024DOI
Dongyang Huang, Julien Siebert, Paolo Sossi, Edith Kubik, Guillaume Avice, Motohiko Murakami
Noble gases in shocked igneous rocks from the 380 Ma-old Siljan impact structure (Sweden): A search for paleo-atmospheric signatures
Chemical Geology· 2024DOI
Fanny Cattani, Guillaume Avice, Ludovic Ferrière, Sanna Alwmark
Ancient atmospheric noble gases preserved in post-impact hydrothermal minerals of the 200 Ma-old Rochechouart impact structure, France
Earth and Planetary Science Letters· 2023DOI
G. Avice, M.A. Kendrick, A. Richard, L. Ferrière
Deliverables (1)
Data Management Plan