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CL 2020/2021 Milutin Milankovic Medal Lectures & 2020 Arne Richter Award for Outstanding ECS Lecture
Conveners: Didier Roche, Irka Hajdas

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Tue, 20 Apr, 10:30–12:30

Chairpersons: Didier Roche, Irka Hajdas

Introduction by Division President Didier M. Roche

Laudation for the 2020 Milutin Milankovic medallist Valérie Masson-Delmotte by Jean Jouzel

Milutin Milankovic Medal Lecture 2020
Valérie Masson-Delmotte

Ice cores provide a wealth of insights into past changes in climate and atmospheric composition.

Obtaining information on past polar temperature changes is important to document climate variations beyond instrumental records, and to test our understanding of past climate variations, including the Earth system response to astronomical forcing.

Since the 1960s, major breakthrough in ice core science have delivered a matrix of quantitative Greenland and Antarctic ice core records.

Temperature reconstructions from polar ice cores document past polar amplification, and provide quantitative constraints to test climate models.

Climate information from the air and ice preserved in deep ice cores has been crucial to unveil the tight coupling between the carbon cycle and climate and the role of past changes in atmospheric greenhouse gas composition in the Earth system response to astronomical forcing.

Ice core constraints on past changes in ice sheet topography are also key to characterize the contribution of the Greenland and Antarctic ice sheets to past sea level changes.

The construction of a common chronological framework for Greenland and Antarctic ice core records has unveiled the bipolar sequence of events during the glacial-interglacial cycle, and the interplay between abrupt change and the response of the climate system to astronomical forcing.

International efforts have started to obtain the oldest ice cores (hopefully back to 1,5 million years) from Antarctica, in order to understand the reasons for the major shifts in the response of the climate system to astronomical forcing at that time, leading to more intense and longer glacial periods. 

How to cite: Masson-Delmotte, V.: Astronomical forcing and climate : insights from ice core records, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-11488, https://doi.org/10.5194/egusphere-egu21-11488, 2021.

Laudation for the 2021 Milutin Milankovic medallist Ayako Abe-Ouchi by Christo Buizert or Kenji Kawamura

Milutin Milankovic Medal Lecture 2021
Ayako Abe-Ouchi

Paleoclimate modelling using simple models, EMICs (Earth System Models of Intermediate Complexity) and GCMs (General Circulation Models) combined with ice sheet models has become a powerful tool for understanding how the long-term climate system with ice sheets responds to external forcings such as Milankovitch forcing. With the aid of supercomputers and advances in climate model development, it is now possible to perform a much larger number of snapshot experiments with fixed forcings as well as transient experiments with evolving forcings. This talk will review the models that simulate the Northern Hemisphere ice sheet change and climate during the ice age cycles and discuss upcoming challenges. The talk will also present recent works on simulating millennial scale climate changes and the link with the ice age cycle. The last termination of the ice age cycles as well as glacial periods were punctuated by abrupt millennial scale climate changes, such as the Bølling-Allerød interstadial, the Younger Dryas and Dansgaard-Oeschger events. Abrupt climate changes have been shown to be strongly linked to changes in the Atlantic Meridional Overturning Circulation (AMOC) and the shift between the (quasi) multiple equilibria of AMOC, but the mechanism behind these abrupt changes and the link to climate change in the orbital scale are not clear. Modelling the stability of AMOC under different climate conditions together with deglacial climate change using fully coupled ocean-atmosphere GCMs has been challenging. Here we present a series of long transient experiments of at least 10,000 years with forcings under different ice sheet sizes, greenhouse gas levels and orbital parameters, as well as deglacial experiments following PMIP4 protocols, using a coupled ocean-atmosphere model, MIROC4m AOGCM. When forcing under glacial condition is applied, even without freshwater perturbation, the climate-ocean system shows self-sustained oscillations within a “sweet spot.” We also see a bipolar seesaw pattern and switching between interstadials and stadials, whose return time ranges from 1,000 years to nearly 10,000 years depending on the background forcing during the ice age cycle. Our transient deglaciation experiment with a gradually changing insolation, greenhouse gas forcing and ice sheet with meltwater from the glacial period to the Holocene is analysed and compared with proxy data as well as with the series of experiments with self-sustained oscillations for a better interpretation. Implications on the role of abrupt climate changes in shaping the longer-term global ice age cycle are further discussed.

How to cite: Abe-Ouchi, A.: Dynamical Ice Sheet-Climate System Response to Astronomical Forcing, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-16573, https://doi.org/10.5194/egusphere-egu21-16573, 2021.

Arne Richter Award for Outstanding ECS Lecture 2020
Francois Massonnet

Polar Regions are viewed by many as "observational deserts", as in-situ measurements there are indeed scarce relative to other regions. The increasing availability of satellite observations does not entirely solve the problem, due to persistent uncertainties in the derived products. Climate models have been instrumental in completing the big picture, but they are themselves subject to errors, some of which are systematic. How to take advantage of the respective strengths of observations and models, while minimizing their respective weaknesses?  To illustrate this point, I will discuss how recent advances in data assimilation, model evaluation, and numerical modeling have enabled progress on addressing important questions in polar research, such as: what are the causes of the recent Antarctic sea ice variability? What might the future of Arctic sea ice look like? How to improve the skill of seasonal sea ice predictions? How should the existing observational network be improved at high latitudes? What are the priorities in terms of modeling? By running through these cases, I will provide support for the emerging hypothesis that "the whole is greater than the sum of its parts": treating observations and climate models as two noisy instances of the same, unknown truth, gives access to answers that would not have been possible using each source separately.

How to cite: Massonnet, F.: Making informed use of observations and climate models to advance understanding of past and future sea ice changes, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-207, https://doi.org/10.5194/egusphere-egu21-207, 2020.


  • Jean Jouzel, LSCE /IPSL, France
  • Christo Buizert, Oregon State University, United States of America
  • Kenji Kawamura, National Institute of Polar Research, Japan
  • Alberto Montanari, University of Bologna, Italy
  • Helen Glaves, British Geological Survey, United Kingdom of Great Britain – England, Scotland, Wales
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