Book contents
- Source-to-Sink Fluxes in Undisturbed Cold Environments
- Source-to-Sink Fluxes in Undisturbed Cold Environments
- Copyright page
- Contents
- Contributors
- Preface
- Part I Solute and sedimentary fluxes and budgets in changing cold climate environments
- Part II Climate change in cold environments and general implications for contemporary solute and sedimentary fluxes
- Part III Solute and sedimentary fluxes in subarctic and Arctic environments
- 5 Contemporary solute and sedimentary fluxes in Arctic and subarctic environments: current knowledge
- 6 The use of dendrogeomorphology to recognize the spatiotemporal distribution of snow avalanches in Northern Iceland – case studies from Dalsmynni, Ljósavatnsskarð, and Fnjóskadalur
- 7 A contemporary assessment of sediment and solute transfers in Kärkevagge, Swedish Lapland
- 8 Hillslope processes and related sediment fluxes on a fine-grained scree slope of Eastern Canada
- 9 Sediment and solute transport from Greenland
- 10 Measurements of bedload flux in a high Arctic environment
- 11 Solute and particulate fluxes in catchments in Spitsbergen
- 12 Sediment and solute fluxes at the Igarka field site, Russian subarctic
- 13 Variability and controls of solute and sedimentary fluxes in subarctic and Arctic environments
- Part IV Solute and sedimentary fluxes in sub-Antarctic and Antarctic environments
- Part V Solute and sedimentary fluxes in alpine/mountain environments
- Part VI Quantitative analysis of solute and sedimentary fluxes in cold climate environments
- Index
- References
7 - A contemporary assessment of sediment and solute transfers in Kärkevagge, Swedish Lapland
from Part III - Solute and sedimentary fluxes in subarctic and Arctic environments
Published online by Cambridge University Press: 05 July 2016
Book contents
- Source-to-Sink Fluxes in Undisturbed Cold Environments
- Source-to-Sink Fluxes in Undisturbed Cold Environments
- Copyright page
- Contents
- Contributors
- Preface
- Part I Solute and sedimentary fluxes and budgets in changing cold climate environments
- Part II Climate change in cold environments and general implications for contemporary solute and sedimentary fluxes
- Part III Solute and sedimentary fluxes in subarctic and Arctic environments
- 5 Contemporary solute and sedimentary fluxes in Arctic and subarctic environments: current knowledge
- 6 The use of dendrogeomorphology to recognize the spatiotemporal distribution of snow avalanches in Northern Iceland – case studies from Dalsmynni, Ljósavatnsskarð, and Fnjóskadalur
- 7 A contemporary assessment of sediment and solute transfers in Kärkevagge, Swedish Lapland
- 8 Hillslope processes and related sediment fluxes on a fine-grained scree slope of Eastern Canada
- 9 Sediment and solute transport from Greenland
- 10 Measurements of bedload flux in a high Arctic environment
- 11 Solute and particulate fluxes in catchments in Spitsbergen
- 12 Sediment and solute fluxes at the Igarka field site, Russian subarctic
- 13 Variability and controls of solute and sedimentary fluxes in subarctic and Arctic environments
- Part IV Solute and sedimentary fluxes in sub-Antarctic and Antarctic environments
- Part V Solute and sedimentary fluxes in alpine/mountain environments
- Part VI Quantitative analysis of solute and sedimentary fluxes in cold climate environments
- Index
- References
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- Information
- Source-to-Sink Fluxes in Undisturbed Cold Environments , pp. 67 - 78Publisher: Cambridge University PressPrint publication year: 2016
References
Allen, C. E., Darmody, R. G., Thorn, C. E., Dixon, J. C., and Schlyter, P. (2001). Clay mineralogy, chemical weathering, and landscape evolution in Arctic-Alpine Sweden. Geoderma, 99, 277–294.CrossRefGoogle Scholar
Angstrőm, A. (1974). Sveriges klimat (Swedish climate) (In Swedish with English summaries). Stockholm: Generalstabens Litografiska Ansyalta Forlag.Google Scholar
Bartsch, A., Gude, M., Jonasson, C., and Scherer, D. (2002). Identification of geomorphic process units in Kärkevagge, northern Sweden, by remote sensing and digital terrain analysis. Geografiska Annaler, 84A, 171–178.CrossRefGoogle Scholar
Barsch, D. (1981). Studien zur gegenwartigen Geomorphodynamik im Bereich der Oobloyah Bay, N-Elllesmer Island N.W.T. Kanada. Heidelberger Geographische Arbeiten, 69, 123–161.Google Scholar
Bartsch, A., Gude, M., and Gurney, S. D. (2008). A geomatics-based approach for the derivation of the spatial distribution of the sediment transport processes in periglacial mountain environments. Earth Surface Processes and Landforms, 33, 2255–2265.CrossRefGoogle Scholar
Bartsch, A., Gude, M., and Gurney, S. D. (2009). Quantifying sediment transport processes in periglacial mountain environments at a catchment scale using geomorphic process units. Geografiska Annaler, 91A, 1–9.Google Scholar
Baumgart-Kotarba, M., Kedzia, S., Kotarba, A., and Mościcki, J. (2001). Geomorphological and geophysical studies in a subarctic environment of Kärkevagge Valley, northern Sweden. Bulletin of the Polish Academy of Sciences: Earth Sciences, 49, 123–135.Google Scholar
Beylich, A. A. (2000). Geomorphology, sediment budget and relief development in Austdalfur, Austfirdir, east Iceland. Arctic, Antarctic and Alpine Research, 32, 466–477.CrossRefGoogle Scholar
Beylich, A. A. (2008a). Mass transfers, sediment budget and relief development in the Latnjavagge catchment, Arctic-oceanic Swedish Lapland. Zeitschrift fur Geomorphologie, 52, Supplement 1, S149–S 197.CrossRefGoogle Scholar
Beylich, A. A. (2008b). Sediment fluxes and sediment budget in Latnjavagge and the potential of applying unified methods for integrating investigations on sediment fluxes and budgets in cold-environment catchments. In Slagstad, T., ed., Geology for Society. Geological Survey of Norway Special Publication, 11, pp. 111–130.Google Scholar
Beylich, A. A. (2012). Major controls of mass transfers and relief development in four cold-climate catchment systems in eastern Iceland, Swedish Lapland and Finish Lapland (Synthesis Paper). Seventh I.A.G./A.I.G. SEDIBUD Workshop and SEDIBUD Summer School, September 10–17, 2012, Trondheim and Loen, Norway. Abstracts and Proceedings of the Geological Society of Norway. No. 1, 87–123Google Scholar
Campbell, S. W., Dixon, J. C., Darmody, R. G., Thorn, , and C. E. (2001). Spatial variation of early season water chemistry in Kärkevagge, Swedish Lapland. Geografiska Annaler, 83A, 169–178.CrossRefGoogle Scholar
Campbell, S. W., Dixon, J. C., and Thorn, C. E. (2002). Chemical denudation rates in Kärkevagge, Swedish Lapland. Geografiska Annaler, 84A, 179–185.CrossRefGoogle Scholar
Darmody, R. G., Thorn, C. E., Schlyter, P., and Dixon, J. C. (2004). Relationship of vegetation distribution to soil properties in Kärkevagge, Swedish Lapland. Arctic Antarctic and Alpine Research, 36, 21–32.CrossRefGoogle Scholar
Darmody, R. G., Thorn, C. E., Harder, R. L., and Dixon, J. C. (2000a). Weathering implications of water chemistry in an Arctic-Alpine environment, northern Sweden. Geomorphology, 34, 89–100.CrossRefGoogle Scholar
Darmody, R. G., Thorn, C. E., Dixon, J. C., and Schlyter, P. (2000b). Soils and landscapes of Kärkevagge, Swedish Lapland. Soil Science Society of America Journal, 64, 1455–1466.CrossRefGoogle Scholar
Eriksson, B. (1982). Data rorande Sveriges temperature-climat (Data concerning air temperature of Sweden). (In Swedish with English summaries). Norrköping: SMHI Reports. Meteorology and Climatology. RMK 39.Google Scholar
French, H. M. (2007). The Periglacial Environment. 3rd edn. Chichester. United Kingdom: John Wiley and Sons.CrossRefGoogle Scholar
Gude, M., Jonasson, C., Dietrich, S., and Scherer, D. (2000). Assessment of variability in fluvial sediment transfers in Kärkevagge (N-Sweden) during the last 50 years. Nordic Hydrology, 31, 373–384.CrossRefGoogle Scholar
Gude, M., Daut, G., Dietrich, S., Mausbacher, R., Jonasson, C., Bartsch, A., and Scherer, D. (2002). Towards an integration of process measurements, archive analysis, and modern geomorphology – the Kärkevagge experimental site, Abisko area, northern Sweden. Geografiska Annaler, 84A, 205–212.CrossRefGoogle Scholar
Jäckli, H. (1957). Gegenwartsgeologie des Bundnerischen Rheingebietes. Beitrag zur geologischen Karte der Schweiz, Geotechnische Seri, 36, 126p.Google Scholar
Jarman, D. (2002). Rock slope failure and landscape evolution in the Caledonian Mountains, as exemplified in the Abisko area, northern Sweden. Geografiska Annaler, 84A, 213–224.CrossRefGoogle Scholar
Karlén, V. (1979). Deglaciation dates from northern Swedish Lapland. Geografiska Annaler, 61A, 203–210.CrossRefGoogle Scholar
Kulander, I., and Nordstrőm, K. (1982). Sedimentproduktion från en flytordsvalk I Kärkevagge. Department of Physical Geography, Upsala University.Google Scholar
Laute, K., and Beylich, A. A. (2014). Environmental controls, rates and mass transfers of contemporary hillslope processes in the headwaters of two glacier-connected drainage basins in western Norway. Geomorphology, 216, 93–113.CrossRefGoogle Scholar
Rapp, A. (1960). Recent development of mountain slopes in Kärkevagge and surroundings northern Scandinavia. Geografiska Annaler, 42, 65–200.Google Scholar
Rapp, A., and Ǻkerman, J. (1993). Slope processes and climate in the Abisko mountains, northern Sweden. In Frenzel, B., ed., Solifluction and Climate Variations in the Holocene. Special Issue: ESF Project “European Paleoclimate and Man .” European Science Foundation. Strasbourg, 163–177.Google Scholar
Rapp, A., and Strőmquist, L. (1979). Field experiments on mass movements in the Scandinavian mountains with special reference to Kärkevagge, Swedish Lapland. Studia Geomorphologica Carpatho-Balcanica, 13, 24–38.Google Scholar
Rehn, J. (1985). Fluvial sediment transport during snowmelt period in periglacial environments as exemplified by Kärkevagge valley, north-western Sweden (in Swedish), Lunds universitets Naturgeografiska institution, Rapporter och Notiser 65, 56–68.Google Scholar
Rehn, J., Stoertz, M., and Stromquist, L. (1982). Geomorphological investigations on erosion, sediment production and fluvial transport along road 98, Kiruna-Riksgransen. Swedish Environmental Protection Board, PM 1522. (In Swedish).Google Scholar
Ridefelt, H., and Boelhouwers, J. (2006). Observations on regional variations in solifluction landform morphology and environment in the Abisko region, northern Sweden. Permafrost and Periglacial Processes, 17, 253–266.CrossRefGoogle Scholar
Ridefelt, H., Boelhouwers, J., and Eiken, T. (2009a). Measurement of solifluction rates using multi-temporal aerial photography. Earth Surface Processes and Landforms, 34, 725–737.CrossRefGoogle Scholar
Ridefelt, H., Akerman, J., Boelhouwers, J., Kolstrup, E., and Nyberg, R. (2009b). 56 years of solifluction measurements in the Abisko mountains, northern Sweden-variations of slow soil surface movement. Geografiska Annaler, 91A, 215–232.CrossRefGoogle Scholar
Sjolin, E., and Rodhe, L. (1977). Studier av flytjordvalkar I Kärkevagge 1976. In Strőmquist, L., Sammanstallning av case studies I naturgeografi. Uppsala: Uppsala University National Geographical Institute.Google Scholar
Soil Survey Staff. (1999). Soil Taxonomy. 2nd edn. U.S.D.A-N.R.C.S. Agricultural Handbook, 436. Washington DC: U.S. Government Printing Office.Google Scholar
Stromquist, L. (1983). Gelifluction and surface wash, their importance and interaction on a periglacial slope. Geografiska Annaler, 65A, 245–254.CrossRefGoogle Scholar
Stromquist, L. (1985). Geomorphic impact of snowmelt on slope erosion and sediment production. Zeitschrift fur Geomorphologie, 29, 129–138.CrossRefGoogle Scholar
Thorn, C. E., Schlyter, P., Darmody, R. G., and Dixon, J. C. (1999). Statistical relationships between daily and monthly air and shallow-ground temperatures in Kärkevagge, Swedish Lapland. Permafrost and Periglacial Processes, 10, 317–330.3.0.CO;2-S>CrossRefGoogle Scholar