Four decades of lake surface temperature in the Northwest Territories, Canada, using a lake-specific satellite-derived dataset
Section 1: Publication
Publication Type
Journal Article
Authorship
Attiah, G., Pour, H. K., Scott, K. A.
Title
Four decades of lake surface temperature in the Northwest Territories, Canada, using a lake-specific satellite-derived dataset
Year
2023
Publication Outlet
Journal of Hydrology: Regional Studies, Volume 50, Elsevier
DOI
ISBN
ISSN
Citation
Attiah, G., Pour, H. K., Scott, K. A. (2023) Four decades of lake surface temperature in the Northwest Territories, Canada, using a lake-specific satellite-derived dataset. Journal of Hydrology: Regional Studies, Volume 50, Elsevier.
https://doi.org/10.1016/j.ejrh.2023.101571
Abstract
Study region:
This study analyzed lake surface temperature (LST) trends and spatial distribution across 535 predominantly small to medium lakes across the North Slave Region (NSR) of the Northwest Territories (NWT), Canada.
Study focus:
The NWT is characterized by a vast number of lakes covering a significant portion of its spatial extent. However, there is limited knowledge of how LST responds to climate warming in this region. To address this, LST was analyzed in four distinct periods: open water season (OW), ice cover season (IC), and the transitional months of May (TM) and October (TO). LSTs from 1984 to 2021 were retrieved from a lake-specific satellite-derived LST dataset (North Slave LST). LST trend distribution and relationships were analyzed using the Mann-Kendall test and a multilinear regression model.
New hydrological insights:
The analysis revealed an overall increase in LST, with average rates (max) of 0.03 °C/year (0.05 °C/year), 0.03 °C/year (0.06 °C/year), and 0.13 °C/year (0.27 °C/year) for OW, TM, and TO, respectively accross study lakes. A faster rate of change was observed in October compared to other periods. Results indicated significant increases in LST for 411 lakes (77%) during OW, 418 lakes (78%) during TO, and 490 lakes (92%) during TM. The spatial distribution and magnitude of LST change were primarily influenced by geographical than morphometric properties. The analysis demonstrated later freeze-up (0.20 day/year) and earlier break-up (−0.17 day/year) of lake ice across the NSR.
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