Plaques de glace permanentes : étude de leurs caractéristiques intrinsèques et de leurs effets sur la dynamique hydrologique et biogéomorphologique des versants du désert polaire arctique

Davesne, Gautier

09 1900

Les plaques de glace forment de petites masses de glace et de neige permanentes qui sont considérées comme un stade intermédiaire dans le continuum neige-glacier. Elles sont omniprésentes dans les régions polaires, ce qui leur confère une fonction centrale dans l’hydrologie et la géomorphologie des versants. Pourtant, très peu d’études s’y sont intéressées jusqu’à présent. Acquérir des connaissances sur ces plaques apparait donc essentiel, non seulement pour comprendre leurs caractéristiques intrinsèques, mais aussi parce que cela ouvre des perspectives importantes pour comprendre la dynamique du géosystème polaire. Afin de répondre à ce besoin, cette thèse cherche à établir l'origine et le fonctionnement des plaques de glace à l’île Ward Hunt (Haut-Arctique canadien) et d’en comprendre les effets sur la dynamique de versant du désert polaire. Cette recherche sur les plaques de glace a été guidée par une approche multidisciplinaire, conduisant à des études glaciologiques, nivologiques, hydrologiques et biogéomorphologiques. Nos résultats ont montré que les plaques de glace se développent par l’aggradation de glace surimposée qui se forme suite au regel de l'eau de fonte à la base de l’accumulation de neige saisonnière. La texture et les propriétés physiques de cette glace varient en fonction de son âge et de l’intensité des processus de recristallisation. La variabilité spatio-temporelle des plaques de glace est principalement contrôlée par la topographie locale et les conditions micrométéorologiques. En hiver, les apports en neige dans les niches topographiques où se forment les plaques de glace sont assurés par le vent. En été, l’intensité de l’ablation est fortement influencée par le vent et le brouillard, qui modulent les échanges d’énergie à la surface des plaques. L'évolution des plaques de glace se caractérise par une stabilité à long terme due à un mécanisme d'autorégulation du bilan de masse assuré par le contexte topoclimatique. Cependant, en raison de leur petite taille, les plaques de glace peuvent disparaître rapidement lorsque l'ablation estivale dépasse un seuil à partir duquel les conditions topoclimatiques ne peuvent plus assurer leur préservation. À Ward Hunt, la présence des plaques de glace depuis au moins plusieurs siècles fait qu’elles ont fortement contribué au développement des versants. Les apports durables en eau et sédiments qui en découlent en été ont enclenché une suite de processus abiotiques et biotiques azonaux dans les marges pronivales. Il en a résulté la formation de systèmes biogéomorphologiques qui consistent en des lobes de solifluxion et des milieux humides colonisés par de la végétation et un couvert de croute biologique. Les modifications morphologiques et physiques du sol en aval des plaques de glace influencent le régime thermique de surface et les profondeurs de dégel. En outre, le développement des zones humides entraine une modification locale des propriétés physiques de la neige en exacerbant le métamorphisme cinétique qui aboutit à la croissance d’une couche de givre de profondeur à la base du manteau neigeux. En apportant une compréhension holistique des plaques de glace polaires, cette thèse permet des avancées empiriques et conceptuelles importantes qui contribuent à mieux comprendre la dynamique du géosystème de désert polaire à un moment charnière où ces environnements subissent en transition rapide en réponse au changement climatique. / Ice patches are small perennial masses of ice and snow that are considered as part of the continuum between seasonal snow and glacier. They are ubiquitous in the Polar Regions, which gives them an important function in slope hydrology and geomorphology. Ice patches have, however, received very little scientific attention so far. Gaining new knowledge on these cryospheric elements thus appears essential, not only to understand their intrinsic characteristics, but also because it holds important perspectives for understanding the dynamics of the polar geosystem. To address this need, this thesis aims to investigate the origin and functioning of the ice patches at Ward Hunt Island (Canadian High Arctic) and to understand their effects on polar desert slope dynamics. This research on ice patches was guided by a multidisciplinary approach, involving glaciological, snow, hydrological and biogeomorphological studies. Our results demonstrated that ice patches develop through the aggradation of superimposed ice that forms by the refreezing of meltwater at the base of the seasonal snowpack. The texture and physical properties of this ice vary according to its age and the intensity of recrystallization processes. The spatio-temporal variability of ice patches is mainly controlled by local topography and micrometeorological conditions. In winter, the snow supply to the topographic niches where ice patches form is provided by the wind. In summer, the intensity of ablation is strongly influenced by wind and fog, which modulate energy exchange at the surface of the patches. The evolution of ice patches is characterized by long-term stability due to a self-regulating mass balance mechanism provided by the topoclimatic context. However, because of their small size, ice patches can disappear very quickly when summer ablation exceeds a threshold at which topoclimatic conditions can no longer ensure their preservation. At Ward Hunt Island, the presence of the ice patches for at least several centuries makes them important drivers of slope development. Sustained meltwater and sediment supplies delivered by ice patches to their pronival margin have triggered a sequence of abiotic and biotic azonal processes. This led to the formation of a biogeomorphic system, consisting of solifluction lobes and humid zones colonized by vegetation and an organic crust cover. Morphological and physical changes in the soil downslope of the ice patches influenced the surface thermal regime and thaw depths. Furthermore, our results show that the humid zone development leads to a local modification of the physical properties of snow by enhancing kinetic metamorphism responsible for the growth of a depth hoar layer at the base of the snowpack. Through a comprehensive understanding of polar ice patches and their effects, this thesis provides important empirical and conceptual advances that contribute to a better understanding of polar desert geosystem dynamics at a pivotal time when these environments are undergoing a rapid transition in response to climate change.

Plaque de glace

Neige

Cryosphère

Nivation

Désert polaire

Solifluxion

Hydrologie

Évolution des versants

Ile Ward Hunt

Ice patch

Snow

Cryosphere

Polar desert

Solifluction

Hydrology

Slope evolution

Ward Hunt Island

Mountains as crossroads : temporal and spatial patterns of high elevation activity in the Greater Yellowstone ecosystem, USA

Reckin, Rachel Jean

January 2018

In the archaeological literature, mountains are often portrayed as the boundaries between inhabited spaces. Yet occupying high elevations may have been an adaptive choice for ancient peoples, as rapidly changing elevations also offer variation in climate and resources over a relatively small area. So what happens, instead, if we put mountain landscapes at the center of our analyses of prehistoric seasonal rounds and ecological adaptation? This Ph.D. argues that, in order to understand any landscape that includes mountains, from the Alps to the Andes, one must include the ecology and archaeology of the highest elevations. Specifically, I base my findings on new fieldwork and lithic collections from the Absaroka and Beartooth Mountains in the Greater Yellowstone Ecosystem (GYE) of the Rocky Mountains, which was a vital crossroads of prehistoric cultures for more than 11,000 years. I include five interlocking analyses. First, I consider the impacts of anthropogenic climate change on high elevation cultural resources, focusing on the diminishing resiliency of ancient high elevation ice patches and the loss of the organic artifacts and paleobiological materials they contain. Second, I create a dichotomous key for chronologically typing projectile points, suggesting a methodological improvement for typological dating in the GYE and for surface archaeology more broadly. Third, I use obsidian source data to consider whether mountain people were a single, unified group or were represented by a variety of peoples with different zones of land tenure. Fourth, I consider high elevation occupation in both mountain ranges as part of the seasonal round, using indices of diversity in tool types and raw material to study how the duration of those occupations changed through time. And, finally, I test the common contention that ancient people primarily used mountains as refugia from extreme climatic pressure at lower elevations. Ultimately, I find that, in both mountain ranges, increased high elevation activity is most highly correlated with increased population, not with hot, dry climatic conditions. In other words, the mountains were more than simply refugia for plains or basin people to occupy when pressured by climatic hardship. In addition, between the Absarokas and the Beartooths the evidence suggests two different patterns of occupation, not a monolithic pan-mountain adaptation. These results demonstrate the potential contributions of surface archaeology to our understanding of prehistory, and have important implications for the way we think about mountain landscapes as peopled spaces in relation to adjacent lower-elevation areas.