Niveau d'étude
Master 2
ECTS
3 crédits
Volume horaire
26h
Période de l'année
Semestre 3
Description
The global carbon cycle, at the heart of major climatic and biogeochemical balances, is not limited to exchanges between the atmosphere, hydrosphere, and surface biosphere. The last decade has highlighted the importance of the deep carbon cycle, still largely unknown, which plays a crucial role in the storage, transformation, and redistribution of carbon within the Earth's envelopes, notably in
organic form, even at high pressures and temperatures. Earth's dynamics – subduction, metamorphism, volcanism, hydrothermalism – control these transfers and, in turn, influence the composition of the atmosphere and the climate on a geological scale. By inducing the abiotic (without the intervention of living organisms) formation of organic compounds and by shaping the chemical disequilibria necessary for all biological activity, this Earth's dynamics is also key to the habitability of our planet.
This course proposes to explore this deep and organic dimension of the carbon cycle on Earth and beyond, and in particular the link between fluid-rock interactions and abiotic organic synthesis in different terrestrial and extraterrestrial contexts. It also revisits the state of knowledge in petroleum geochemistry, and especially the methods of characterization of organic matter now applied to the deep and organic carbon cycle.
Objectifs
- Understanding the redox dynamics of carbon in deep environments (terrestrial and extraterrestrial) and the links with fluid-rock interactions, particularly hydrogen production.
- Becoming familiar with recent knowledge acquired on the deep carbon cycle.
- Knowing a wide range of characterization techniques (principle and applicability) for organic matter within rocks.
Heures d'enseignement
- Organics in the Earth and beyondCours Magistral22h
- Organics in the Earth and beyondTravaux Dirigés4h
Pré-requis nécessaires
Basic knowledge in organic geochemistry is useful but not mandatory.
Dernière mise à jour le 3 juin 2025