Fine‐scale environment control on ground surface temperature and thaw depth in a High Arctic tundra landscape

Author:

Khani Hadi Mohammadzadeh12ORCID,Kinnard Christophe12,Gascoin Simon3,Lévesque Esther12

Affiliation:

1. Centre de Recherche sur les Interactions Bassins Versants—Écosystèmes Aquatiques (RIVE), Département des Sciences de l'Environnement Université du Québec à Trois‐Rivières Trois‐Rivières Quebec Canada

2. Centre d'Études Nordiques (CEN) Quebec Quebec Canada

3. Centre d'Études Spatiales de la Biosphère (CESBIO), Université de Toulouse, CNRS/CNES/IRD/INRAE/UPS Toulouse France

Abstract

AbstractSurface conditions are known to mediate the impacts of climate warming on permafrost. This calls for a better understanding of the environmental conditions that control the thermal regime and the depth of the active layer, especially within heterogeneous tundra landscapes. This study analyzed the spatial relationships between thaw depths, ground surface temperature (GST), and environmental conditions in a High Arctic tundra environment at Bylot Island, Nunavut, Canada. Measurements were distributed within the two dominant landforms, namely earth hummocks and low‐center polygons, and across a topographic gradient. Our results revealed that GST and thaw depth were highly heterogeneous, varying by up to 3.7°C and by more than 20 cm over short distances (<1 m) within periglacial landforms. This microscale variability sometimes surpassed the variability at the hillslope scale, especially in summer. Late‐winter snowpack thickness was found to be the prime control on the spatial variability in winter soil temperatures due to the highly heterogeneous snow cover induced by blowing snow, and this thermal effect carried over into summer. However, microtopography was the predominant driver of the spatial variability in summer GST, followed by altitude and moss thickness. In contrast, the spatial variability in thaw depth was influenced predominantly by variations in moss thickness. Hence, summer microclimate conditions dominated active layer development, but a thicker snowpack favored soil cooling in the following summer, due to the later disappearance of snow cover. These results enhance our understanding of High Arctic tundra environments and highlight the complexity of considering surface feedback effects in future projections of permafrost states within heterogeneous tundra landscapes.

Funder

Natural Sciences and Engineering Research Council of Canada

Canada Excellence Research Chairs, Government of Canada

Publisher

Wiley

Subject

Earth-Surface Processes

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