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
12 - Sediment and solute fluxes at the Igarka field site, Russian subarctic
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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- Source-to-Sink Fluxes in Undisturbed Cold Environments , pp. 144 - 153Publisher: Cambridge University PressPrint publication year: 2016
References
Asselman, N. E. M. (2000). Fitting and interpretation of sediment rating curves. Journal of Hydrology, 234, 228–248.CrossRefGoogle Scholar
Astakhov, V., and Isayeva, L. (1988). The “Ice Hill”: an example of “retarded deglaciation” in Siberia. Quaternary Science Reviews, 7, 29–40.CrossRefGoogle Scholar
Colby, B. R. (1956). Relationship of sediment discharge to streamflow. U.S. Geological Survey Open File Report 56–27, Washington, DC, 169 p.Google Scholar
Ferguson, R. (1986). Hydraulics and hydraulic geometry. Progress in Physical Geography, 10, 1–31.CrossRefGoogle Scholar
Guggenberger, G., Rodionov, A., Shibistova, O., Grabe, M., Kazansky, O., Fuchs, H., Mikheyeva, N., Zrazhevskaya, G., and Flessa, H. (2008). Storage and mobility of black carbon in permafrost soils of the forest tundra ecotone in Northern Siberia. Global Change Biology, 14, 1367–1381.CrossRefGoogle Scholar
Lebedeva, L., and Semenova, O. (2011). Evaluation of climate change impact on soil and snow processes in small watersheds of European part of Russia using various scenarios of climate. Die Bodenkultur, 62(1–4), 77–82.Google Scholar
Old, G., Lawler, D., and Snorrason, Á. (2005). Discharge and suspended sediment dynamics during two jökulhlaups in the Skaftáriver, Iceland, Earth Surface. Processes and Landforms, 30, 1441–1460.CrossRefGoogle Scholar
Peel, M., Finlayson, B., and McMahon, T. (2007). Updated world map of the Köppen-Geiger climate classification. Hydrology and Earth System Sciences, 11, 1633–1644.CrossRefGoogle Scholar
RD 52.08.104–2002 (2002). Methodical guide. Suspended sediment concentration. Moscow: Meas. Tech., 32 pp.Google Scholar
Rodionov, A., Flessa, H., Grabe, M., Kazansky, O., Shibistova, O., and Guggenberger, G. (2007). Organic carbon and total nitrogen variability in permafrost-affected soils in a forest tundra ecotone. European Journal of Soil Science, 58, 1260–1272.CrossRefGoogle Scholar
Sergievskaya, Ya., Poznarkova, S., and Tananaev, N. (2012). Monitoring of the depth of seasonal thawing in the lower reaches of the Yenisey river at site CALM R-40 of Igarka town // Tenth International Conference on Permafrost: Resources and Risks of Permafrost Areas in a Changing World. Vol.4/1: Extended Abstracts. Fort Dialog-Iset: Ekaterinburg, Russia, 514–515.Google Scholar
Tananaev, N. (2014a). Estimation of the annual discharge of suspended matter by the rivers of North Siberia and the Far East. Oceanology, 54 (5), 650–659.CrossRefGoogle Scholar
Tananaev, N. (2014b). Fitting sediment rating curves using regression analysis: a case study of Russian Arctic rivers, IAHS Publ. 367, Wallingford, UK: IAHS Press, 193–198.Google Scholar
Tananaev, N., and Debolskiy, M. (2014). Turbidity observations in sediment flux studies: Examples from Russian rivers in cold environments. Geomorphology, 218, 63–71.CrossRefGoogle Scholar
US EPA Method 180.1. (1993). Determination of turbidity by nephelometry. Revision 2.0.August 1993. Cincinnati, OH: U.S. Environment Protection Agency, 10 p.Google Scholar
Vinogradov, Yu., Semenova, O., and Vinogradova, T. (2011). An approach to the scaling problem in hydrological modelling: the deterministic modelling hydrological system. Hydrological Processes, 25 (7), 1055–1073.CrossRefGoogle Scholar
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