Videos: Post-Little Ice Age rock wall permafrost evolution in Norway
Creators
- 1. Department of Geosciences, University of Oslo, 0316 Oslo, Norway
- 2. Department of Research and Development, Norwegian Meteorological Institute, 0313 Oslo, Norway
- 3. EDYTEM, Université Savoie Mont-Blanc, CNRS, 73000 Chambery, France
Description
Videos for Czekirda, J., Etzelmüller, B., Westermann, S., Isaksen, K., and Magnin, F.: Post-Little Ice Age rock wall permafrost evolution in Norway, The Cryosphere, 17, 2725–2754, https://doi.org/10.5194/tc-17-2725-2023, 2023.
Video captions:
Video 1. Mannen: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 2. Mannen: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 3. Ramnanosi: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 4. Ramnanosi: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 5. Hogrenningsnibba: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 6. Hogrenningsnibba: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 7. Kvernhusfjellet: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 8. Kvernhusfjellet: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 9. Veslpiggen: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 10. The lower part of Veslpiggen: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 11. Veslpiggen: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 12. Galdhøe: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 13. The lower part of Galdhøe: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 14. Galdhøe: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 15. Gámanjunni 3: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 16. Gámanjunni 3: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 17. Ádjit: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 18. Ádjit: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Video 19. Rombakstøtta: Modelled maximum annual ground temperature over the years 1900–2020 for the various simulations.
Video 20. Rombakstøtta: Modelled mean annual ground temperature over the years 1900–2020 for the various simulations. Arrows show direction of heat fluxes for temperature field interpolated to 20 x 20 m grid cells.
Files
Video01.mp4
Files
(117.3 MB)
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Additional details
Related works
- Is cited by
- Journal article: 10.5194/tc-17-2725-2023 (DOI)