FRENCH ARCTIC INITIATIVE SCIENTIFIC PRIORITIES

FRENCH ARCTIC INITIATIVE SCIENTIFIC PRIORITIES J.J. Pangrazi / Biosphoto J.J. Pangrazi / Biosphoto Conference audience Edouard Bard introductory lecture Dr. Denis-Didier Rousseau (CNRS Senior Research Scientist, Scientific Director of the French Arctic Initiative) Ottawa, 9 December 2014

The scoping exercise of the French Arctic Initiative : The process Extending the discussion to all disciplines and all of the French scientific community interested in scientific issues in Arctic. To encourage multidisciplinary discussions, this scoping exercise was designed through 9 themes: Permafrost, Biodiversity and Ecosystems, Climate: Atmosphereice-ocean, Geodynamics and natural resources, the anthropisation and its impacts, Governance and Geopolitics, Arctic societies and systems of knowledge, Observations, Modeling. Audience targeted: All French scientists who study or wish to invest in scientific research on Arctic-specific themes were invited to participate. Experts, not necessarily focused on a particular environment, which could also contribute to the development of a more innovative research in the Arctic.

The scoping exercise of the French Arctic Initiative : The format of the Science Plan The document is in the press and will be released in the upcoming weeks. The Science plan consists of a total of 10 major research priorities defined on the basis of the information gathered during all the scoping process. Its aim is to stimulate and foster interactions between different disciplines. The science plan also includes an inventory of forces and a series of recommendations on the means of observation and modeling to strengthen or develop. These priorities are presented in an order going from the more specific to the more inclusive.

1. Arctic and global atmospheric variability: amplification, couplings and impacts. Objective: Identifying connections between Arctic variability and global climate as well as understanding the underlying atmospheric mechanisms such as transport, surface-troposphere-stratosphere couplings and teleconnections. Clarifying the impact of the Arctic cryosphere on global atmospheric variability and, conversely, the impact of dynamic anomalies in the lower latitudes on the modes of atmospheric variability in the Arctic. Improving our understanding of the mechanisms responsible for polar amplification and identifying the major feedbacks. Assessing the current warming in the Arctic and the ability of climate models to represent it, in the light of past climates, identifying its impacts on human activities and measuring how indigenous peoples perceive them. Predicting what Arctic warming will be during the next century.

2. Water cycle and land ice. Objective: Improving our understanding of the different compartments governing the Earth water cycle and their impact on climate. Improving our understanding and modelling the evolution of Arctic land ice masses to anticipate their future and improve climate scenarios. Monitoring the contribution of the decline in Arctic land ice (glaciers and small ice caps, Green-land ice sheet) volume to sea level rise and their impacts. Characterizing the past evolution of land ice masses to help understand their current changes and to assess the ability of our tools (observation and modelling) to represent them.

3. A changing ocean: from the physical environment to marine ecosystems. Objective: Studying the variability of the Arctic Ocean and the changes related to climate evolution. Improving our understanding of the processes that control the distribution of Arctic sea ice to improve predictions of the ice conditions in the Arctic at local and global scales. Evaluating the links between regional changes and global ocean variability. Identifying key interactions between the physical environment (ocean and marine cryosphere) and marine biogeochemical cycles. Studying the combined effects of ongoing changes in the Arctic Ocean on the all (benthic or pelagic, coastal to offshore) marine eco-systems in the Arctic Ocean, from the microbial loop and primary production to vertebrates, to help especially develop future ecological scenarios for coastal populations.

4. Geodynamics and resources. Objective: Reconstructing the long-term physiography and palaeogeography of Arctic basins. Modelling the impact of this physiography on water and sediment fluxes. Incorporating organic matter into margin sedimentology. Integrating mantle (dynamic topography, hotspots), lithosphere (subduction, thermal relaxation) and crustal processes in the model of Arctic basin formation. Identifying the specific characteristics of peri-arctic areas in terms of resources.

5. Permafrost dynamics in the context of climate warming. Objective: The regions below the Arctic Circle with permanent frozen soil (permafrost) bear the brunt of the consequences of climate warming leading to the development of periglacial landforms associated with the thawing of this frozen ground. The increase in air temperature has caused an increase in the temperature of the frozen soil (1 C) since the 1980s and a deepening of the active layer (surface layer thaws in summer). Model results according to IPCC climate scenarios indicate that, in the mid 21st century, the area of permafrost in the Northern Hemisphere is likely to decline by 35% to 80%, mainly due to melting permafrost. Studies indicate that in 2050, the depth of seasonal thawing could increase by 15% to 25% or even 50% in the northernmost regions. The thawing of permafrost may release greenhouse gases that will accelerate warming and disrupt hydrological systems and ground stability with implications for socio-ecosystems. All of these phenomena lead to strong feedbacks between the climate, vegetation, snow, permafrost and hydrology.

6. Arctic terrestrial ecosystem dynamics in the context of global change. Objective: Assessing the impact of global change on ecosystems and the evolution of terrestrial organisms, the dynamics of trophic networks in which they participate and the consequences of these processes for changing Arctic landscapes.

7. Indigenous people and global change. Objective: Evaluating the impact that global changes have on the evolution of Arctic ecosystems and on the experiences of Indigenous people. Grasping the complex linkages between these changes and the values held by the societies involved, taking into account past and present situations. Analysing the solutions already implemented or proposed by comparing the diverse scientific and local knowledge. Establishing ethical partnerships opening the door to integrated points of view given a comprehensive approach to the phenomena.

8. Towards an integrated program on the Arctic Land-Sea continuum. Objective: Transfers between the land surface and Arctic Ocean occur along a continuum and it is important not to separate the compartments: they are all interdependent. The scientific objective is to understand the mechanisms, to determine the fluxes and their impact on Arctic ecosystems and societies, from the continental watersheds to the ocean where the sedimentary archives are on the margins.

9. Pollution: sources, cycles and impacts. Objective: The Arctic is particularly sensitive to anthropogenic pollutants that can have deleterious effects on ecosystems, human health and climate. It is therefore important to improve the quantification of anthropogenic (and natural) sources of pollution, local and remote, and to better characterize the transformation processes and their impact on the physical environment (atmosphere, ocean, cryosphere, soil, lakes) and local populations in the Arctic region. Currently, a major challenge is to better understand human impacts related to economic development and Arctic warming.

10. Sustainable development in the Arctic region: impacts, implementation and governance. Objective: The research objective is to assess the impact of economic activities in different sectors (ports, land and sea transport, extraction of mineral resources and hydrocarbons) on the environment (such as pollution) and on societies (social, health and cultural impacts) on a fine scale (community, city, tourist and industrial ports, mining site) and globally (shipping routes, possible extension of fishing activities to the high seas). The objective includes social, environmental, legal, political and health components. It will contribute to the quality of life index and the analysis of governance mechanisms defined as the process of cooperation and accommodation by which individuals and institutions, public and private, manage their common affairs (Commission on Global Governance, 1995) to produce results in terms of strategic options (scenarios) presented to policy makers.

WHAT S UP AFTER THIS FIRST MAIN STEP? This Science Plan is part of the upcoming French National Roadmap on the Arctic. The French Arctic Initiative permitted to reinforce on-going international collaborations and cooperations (MoUs recently signed with CPC, and with ArcticNet), and new partnerships (see ECRA-Arctic, EU-PolarNet) are presently built on this new science plan. Although not an Arctic country, and while physically present in the Arctic through the AWIPEV base in Ny Alesund and the mix CNRS-Uni. Laval laboratory Takuvik, the French Scientific Community is now organized and structured to tackle these identified transdisciplinary priorities through the new multi-year program that we are launching by the end of the year. Ottawa, 9/12/2014

THANK YOU FOR YOUR ATTENTION Contact: Denis-Didier Rousseau denis-didier.rousseau@cnrs-dir.fr (www.chantier-arctique.fr) Ottawa, 9/12/2014