Description du projet
Impact du changement climatique sur les éruptions volcaniques
Les éruptions volcaniques rejettent dans l’atmosphère des gaz sulfureux qui modifient le bilan énergétique de la Terre et provoquent un refroidissement à la surface de la Terre. Le refroidissement consécutif aux éruptions de grande envergure peut avoir une grande incidence sur la société et contribuer à atténuer le réchauffement climatique. Cela dit, les processus qui régissent le refroidissement de la surface conjugués à une éruption sont eux-mêmes sensibles au climat. Le transport des gaz volcaniques est notamment régi par la circulation atmosphérique. Le projet VOLCPRO, financé par l’UE, vise à étudier l’influence du cycle de vie des gaz volcaniques sur le changement climatique, et à évaluer si le refroidissement volcanique s’en verra renforcé ou atténué avec le réchauffement de la Terre.
Objectif
Volcanic eruptions injecting gases into the stratosphere modify Earth’s radiative balance and atmosphere chemistry, which in turn impacts all components of the Earth system. The surface cooling that follows large eruptions can have major societal impacts and volcanic eruptions contribute to mitigate global warming. Yet, climate model projections use simplistic representation of this key forcing and commonly assume a constant volcanic forcing in the future. The most realistic projections only represent very large and rare eruptions, and ignore how climate change will affect the rise of volcanic plumes, the evolution of the associated aerosol clouds and the subsequent climate impacts.
To improve the representation of volcanic forcing in climate model projections, I will address two fundamental questions:
1) How does a statistically realistic representation of volcanic eruptions of all magnitude in climate models affect projected climate changes?
2) How will climate-volcano feedbacks modulate the impact of future volcanic eruptions on climate?
To answer them, I will perform a suite of experiments with the United Kingdom’s flagship Earth system model, UKESM1, which is a fully coupled aerosol-chemistry-climate model. These experiments are aimed to feed the designing of future climate projections.
During the fellowship, I will gain brand-new skills in climate modeling and be trained by world-leading experts in this field. I will combine these skills with my expertise in physical volcanology to address the proposed research questions and, in particular, improve our understanding of climate-volcano interactions in the context of global climate change. The fellowship will enable me to become an interdisciplinary leader in climate-volcano research and will constitute a stepping stone towards new research opportunities and applications for a tenure-track position.
Champ scientifique
Programme(s)
Régime de financement
MSCA-IF-EF-ST - Standard EFCoordinateur
CB2 1TN Cambridge
Royaume-Uni