Surface temperature measurements near Ny-Ålesund, Svalbard, Norway in 2008 with links to data files

The ground surface temperature is one of the key parameters that determine the thermal regime of permafrost soils in arctic regions. Due to remoteness of most permafrost areas, monitoring of the land surface temperature (LST) through remote sensing is desirable. However, suitable satellite platforms...

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Bibliographic Details
Main Authors: Westermann, Sebastian, Langer, Moritz, Boike, Julia
Format: Dataset
Language:English
Published: PANGAEA 2011
Subjects:
AWI_PerDyn
AWIPEV
DATE/TIME
NYA_LH_2008
NYA_Meteorological_Obs
Ny-Ålesund
Spitsbergen
Permafrost Research (Periglacial Dynamics) @ AWI
Thermal imaging system
TIS
Uniform resource locator/link to image
Uniform resource locator/link to raw data file
Uniform resource locator/link to thumbnail
Arctic
Norway
Svalbard
Ny Ålesund
permafrost
Tundra
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.746674
https://doi.org/10.1594/PANGAEA.746674
Description
Summary:The ground surface temperature is one of the key parameters that determine the thermal regime of permafrost soils in arctic regions. Due to remoteness of most permafrost areas, monitoring of the land surface temperature (LST) through remote sensing is desirable. However, suitable satellite platforms such as MODIS provide spatial resolutions, that cannot resolve the considerable small-scale heterogeneity of the surface conditions characteristic for many permafrost areas. This study investigates the spatial variability of summer surface temperatures of high-arctic tundra on Svalbard, Norway. A thermal imaging system mounted on a mast facilitates continuous monitoring of approximately 100 x 100 m of tundra with a wide variability of different surface covers and soil moisture conditions over the entire summer season from the snow melt until fall. The net radiation is found to be a control parameter for the differences in surface temperature between wet and dry areas. Under clear-sky conditions in July, the differences in surface temperature between wet and dry areas reach up to 10K. The spatial differences reduce strongly in weekly averages of the surface temperature, which are relevant for the soil temperature evolution of deeper layers. Nevertheless, a considerable variability remains, with maximum differences between wet and dry areas of 3 to 4K. Furthermore, the pattern of snow patches and snow-free areas during snow melt in July causes even greater differences of more than 10K in the weekly averages. Towards the end of the summer season, the differences in surface temperature gradually diminish. Due to the pronounced spatial variability in July, the accumulated degree-day totals of the snow-free period can differ by more than 60% throughout the study area. The terrestrial observations from the thermal imaging system are compared to measurements of the land surface temperature from the MODIS sensor. During periods with frequent clear-sky conditions and thus a high density of satellite data, weekly averages ...

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