1,100 km in Antarctica to better understand the evolution of the ice cap

Field measurements of unprecedented scope

Rising water levels in the future, in the context of global warming, mostly depend on the quantity of water stored in the form of snow and ice within the Antarctic ice cap. But through which atmospheric processes does snow accumulate each day on the ice cap’s surface? 
The AWACA project¹ will make field measurements of unprecedented scope in order to improve our knowledge of the atmospheric aspects of the water cycle and snow formation in Antarctica. The observations made regarding our climate will greatly improve climate models, with the goal of eventually reconstructing the climate variability for Antarctica over the last millennium, and predicting that of the next 100 years.

A long-distance scientific trek stretching 1,100 km

From 2 December 2024 until mid-January 2025, a scientific trek conceived by the French Polar Institute will deploy measurement and observation instruments along a 1,100 km transect representative of the various climate regions of East Antarctica, from the Dumont d'Urville station on the coast to the Concordia station in the middle of the Antarctic Plateau. This transect is aligned with the typical trajectory of the air masses that transport humidity from the ocean toward the continent’s interior.  
The fruit of a three-year technical and instrumental effort, the observation systems specially designed for the project will provide accurate data for the properties of the droplets and crystals that form clouds and precipitation, as well as for how they contribute to the accumulation of snow on the surface. A major component of the project will also focus on studying water isotopes, invaluable sources of information on the origin of air masses and their successive changes of state. The results will also refine our interpretation of measurements made in ice cores, in addition to our knowledge of past climates.

A logistical challenge to optimise next generation climate models

Once in place, the observation systems located along the transect will make readings continuously, and for those located outside of permanent stations entirely autonomously as well, including with respect to the 1000 W of energy needed for their functioning. They can operate for at least three years in the extreme weather conditions of Antarctica, a technical feat! Annual maintenance will be provided by the teams during Antarctic summer campaigns via the deployment of long-distance control treks. The collected data will be analysed to help optimise next generation climate models.

The AWACA project is co-directed by scientists from the CNRS, the CEA, l’École polytechnique of Paris, and the Swiss Federal Technology Institute of Lausanne working in the Dynamic Meteorology Laboratory (IPSL², CNRS/Ecole polytechnique/ENS – PSL/Sorbonne Université), the Laboratory of Climate and Environmental Sciences (IPSL, CEA/CNRS/Université Versailles Saint-Quentin), and the Atmospheric Space Observations Laboratory (IPSL, CNRS/Sorbonne Université/ Université Versailles Saint-Quentin) in France, in addition to the EPFL’s Environmental Remote Sensing Laboratory in Switzerland. A true logistical challenge in polar weather conditions, the deployment of instruments was made possible thanks to the know-how and experience of the French Polar Institute.

The research project involves technicians, engineers, and researchers, in addition to specialists in meteorological observations, instrumentation in extreme conditions, and atmosphere and climate modelling.

This research received funding from the European Research Council in the form of an ERC Synergy Grant3.

Follow AWACA on the project’s website.