Special Issue Article
Controls on snowmelt water mean transit times in northern boreal catchments
Steve W. Lyon,
Hjalmar Laudon,
Jan Seibert,
Magnus Mörth,
Doerthe Tetzlaff,
Kevin H. Bishop,
Corresponding Author
Steve W. Lyon
Department of Physical Geography and Quaternary Geology, Stockholm University, Stockholm, Sweden
Department of Physical Geography and Quaternary Geology, Stockholm University, 106 91 Stockholm, Sweden.===Search for more papers by this authorHjalmar Laudon
Department of Forest Ecology and Management, SLU, Umeå, Sweden
Search for more papers by this authorJan Seibert
Department of Physical Geography and Quaternary Geology, Stockholm University, Stockholm, Sweden
Department of Geography, University of Zurich, Zurich, Switzerland
Search for more papers by this authorMagnus Mörth
Department of Geology and Geochemistry, Stockholm University, Stockholm, Sweden
Search for more papers by this authorDoerthe Tetzlaff
School of Geosciences, University of Aberdeen, Aberdeen, Scotland
Search for more papers by this authorKevin H. Bishop
Department of Aquatic Sciences and Assessment, SLU, Uppsala, Sweden
Search for more papers by this authorSteve W. Lyon,
Hjalmar Laudon,
Jan Seibert,
Magnus Mörth,
Doerthe Tetzlaff,
Kevin H. Bishop,
Corresponding Author
Steve W. Lyon
Department of Physical Geography and Quaternary Geology, Stockholm University, Stockholm, Sweden
Department of Physical Geography and Quaternary Geology, Stockholm University, 106 91 Stockholm, Sweden.===Search for more papers by this authorHjalmar Laudon
Department of Forest Ecology and Management, SLU, Umeå, Sweden
Search for more papers by this authorJan Seibert
Department of Physical Geography and Quaternary Geology, Stockholm University, Stockholm, Sweden
Department of Geography, University of Zurich, Zurich, Switzerland
Search for more papers by this authorMagnus Mörth
Department of Geology and Geochemistry, Stockholm University, Stockholm, Sweden
Search for more papers by this authorDoerthe Tetzlaff
School of Geosciences, University of Aberdeen, Aberdeen, Scotland
Search for more papers by this authorKevin H. Bishop
Department of Aquatic Sciences and Assessment, SLU, Uppsala, Sweden
Search for more papers by this authorAbstract
Catchment-scale transit times for water are increasingly being recognized as an important control on geochemical processes. In this study, snowmelt water mean transit times (MTTs) were estimated for the 15 Krycklan research catchments in northern boreal Sweden. The snowmelt water MTTs were assumed to be representative of the catchment-scale hydrologic response during the spring thaw period and, as such, may be considered to be a component of the catchment's overall MTT. These snowmelt water MTTs were empirically related to catchment characteristics and landscape structure represented by using different indices of soil cover, topography and catchment similarity. Mire wetlands were shown to be significantly correlated to snowmelt MTTs for the studied catchments. In these wetlands, shallow ice layers form that have been shown to serve as impervious boundaries to vertical infiltration during snowmelt periods and, thus, alter the flow pathways of water in the landscape. Using a simple thought experiment, we could estimate the potential effect of thawing of ice layers on snowmelt hydrologic response using the empirical relationship between landscape structure (represented using a catchment-scale Pe number) and hydrologic response. The result of this thought experiment was that there could be a potential increase of 20–45% in catchment snowmelt water MTTs for the Krycklan experimental catchments. It is therefore possible that climatic changes present competing influences on the hydrologic response of northern boreal catchments that need to be considered. For example, MTTs may tend to decrease during some times of the year due to an acceleration in the hydrologic cycle, while they tend to increase MTTs during other times of the year due to shifts in hydrologic flow pathways. The balance between the competing influences on a catchment's MTT has consequences on climatic feedbacks as it could influence hydrological and biogeochemical cycles at the catchment scale for northern latitude boreal catchments. Copyright © 2010 John Wiley & Sons, Ltd.
REFERENCES
- Ågren A, Buffam I, Jansson M, Laudon H. 2007. Importance of seasonality and small streams for the landscape regulation of DOC export. Journal of Geophysical Research-Biogeosciences 112: G03003. DOI: 10.1029/2006 JG000381.
- Barnes CJ, Bonell M. 1996. Application of unit hydrograph techniques to solute transport in catchments. Hydrological Processes 10(6): 793–802. DOI:10.1002/(SICI)1099-1085(199606)10:6 < 793::AID-HYP372 > 3.0.CO;2-K.
- Berne A, Uijlenhoet R, Troch PA. 2005. Travel time distributions of subsurface flow along complex hillslopes with exponential width functions. Water Resources Research 41: W09410. DOI: 10.1029/2004WR003629.
- Beven KJ, Kirkby MJ. 1979. Towards a simple, physically based, variable contributing area model of catchment hydrology. International Association of Hydrological Sciences Bulletin 24: 43–69.
10.1080/02626667909491834 Google Scholar
- Bishop KH, Grip H, O'Neill A. 1990. The origin of acid runoff in a hillslope during storm events. Journal of Hydrology 116: 35–61.
- Bishop K, Seibert J, Köhler S, Laudon H. 2004. Resolving the Double Paradox of rapidly mobilized old water with highly variable responses in runoff chemistry. Hydrological Processes 18: 185–189. DOI: 10.1002/hyp.5209.
- Bogaart PW, Troch PA. 2006. Curvature distribution within hillslopes and catchments and its effect on the hydrological response. Hydrology and Earth System Sciences 10: 925–936.
- Broxton PD, Troch PA, Lyon SW. 2009. On the role of aspect to quantify water transit times in small mountainous catchments. Water Resources Research 45: W08427. DOI:10.1029/2008WR007438.
- Brutsaert W. 1994. The unit response of groundwater outflow from a hillslope. Water Resources Research 30(10): 2759–2763.
- Buffam I, Laudon H, Temnerud J, Mörth C-M, Bishop K. 2007. Landscape-scale variability of acidity and dissolved organic carbon during spring flood in a boreal stream network. Journal of Geophysical Research 112: G01022. DOI: 10.1029/2006JG000218.
- Buttle J. 2006. Mapping first-order controls on streamflow from drainage basins: the T3 template. Hydrological Processes 20: 3415–3422.
- Carey SK, Woo MK. 2001. Slope runoff processes and flow generation in a subarctic, subalpine catchment. Journal of Hydrology 253: 110–129.
- Coplen TB. 1995. Reporting of stable hydrogen, carbon and oxygene isotopic abundances. Geothermics 24: 707–712.
- Déry SJ, Stieglitz M, McKenna EC, Wood EF. 2005. Characteristics and trends of river discharge into Hudson, James, and Ungava Bays, 1964–2000. Journal of Climate 18: 2540–2557.
- Dunn SM, McDonnell JJ, Vache KB. 2007. Factors influencing the residence time of catchment waters: A virtual experiment approach. Water Resources Research 43: W06408. DOI:10.1029/2006WR005393.
- Harman CJ, Sivapalan M. 2009. A similarity framework to assess controls on shallow subsurface flow dynamics. Water Resources Research 45: W01417. DOI: 10.1029/2008WR007067.
- Hinzman LD, Kane DL, Everett KR. 1993. Hillslope hydrology in an Arctic setting. Proceedings, Sixth International Conference on Permafrost. South China Press: Beijing; 257–271.
- Hrachowitz M, Soulsby C, Tetzlaff D, Dawson JJC, Malcolm IA. 2009a. Regionalization of transit time estimates in montane catchments by integrating landscape controls. Water Resources Research 45: W05421. DOI: 10.1029/2008WR007496.
- Hrachowitz M, Soulsby C, Tetzlaff D, Dawson JJC, Dunn SM, Malcolm IA. 2009b. Using longer-term data sets to understand transit times in contrasting headwater catchments. Journal of Hydrology 367(3): 237–248.
- Hjerdt KN, McDonnell JJ, Seibert J, Rodhe A. 2004. A new topographic index to quantify downslope controls on local drainage. Water Resources Research 40: W05602. DOI:10.1029/2004WR003130.
- Kane DL, Bredthauer SR, Stein J. 1981. Subarctic snowmelt runoff generation. In Proceedings of the Specialty Conference on the Northern Community, TS Vinson (ed.). American Society of Civil Engineers: Seattle, WA; 591–601.
- Kirchner JW, Feng X, Neal C. 2000. Fractal stream chemistry and its implications for contaminant transport in catchments. Nature 403(6769): 524–527. DOI:10.1038/35000537.
- Kirchner JW, Feng X, Neal C. 2001. Catchment-scale advection and dispersion as a mechanism for fractal scaling in stream tracer concentrations. Journal of Hydrology 254: 82–101.
- Klaminder J, Bindler R, Laudon H, Bishop K, Emteryd O, Renberg I. 2006. Flux rates of atmospheric lead pollution within soils from a small catchment in northern Sweden and their implication for future stream water quality. Environmental Science and Technology 40: 4639–4645.
- Köhler SJ, Buffam I, Laudon H, Bishop KH. 2008. Climate's control of intra-annual and inter-annual variability of total organic carbon concentration and flux in two contrasting boreal landscape elements. Geophysical Research Biogeosciences 113: G03012. DOI: 10.1029/2007JG000629.
- Laudon H, Köhler S, Seibert J, Bishop KH. 2004. Hydrological flow paths during the spring flood: Congruence between hydrometric measurements and oxygen-18 in snow melt, soil water, and runoff. Water Resources Research 40(3): W03102. 10.1029/2003WR002455.
- Laudon H, Sjöblom V, Buffam I, Seibert J, Mörth M. 2007. The role of catchment scale and landscape characteristics for runoff generation of boreal streams. Journal of Hydrology 344: 198–209.
- Lyon SW, Destouni G. 2009. Changes in catchment-scale recession flow properties in response to permafrost thawing in the Yukon River Basin. International Journal of Climatology (in press), DOI: 10.1002/joc.1993.
- Lyon SW, Troch PA. 2007. Hillslope subsurface flow similarity: real-world tests of the hillslope Péclet number. Water Resources Research. 43: W07450. DOI: 10.1029/2006WR005323.
- Lyon SW, Troch PA. 2009. Development and application of a catchment similarity index for subsurface flow. Water Resources Research in review.
- Lyon SW, Desilets SLE, Troch PA. 2008. Characterizing the response of a catchment to an extreme rainfall event using hydrometric and isotopic data. Water Resources Research 44: W06413. DOI: 10.1029/2007WR006259.
- Lyon SW, Destouni G, Giesler R, Humborg C, Mörth M, Seibert J, Karlsson J, Troch PA. 2009. Estimation of permafrost thawing rates in a sub-arctic catchment using recession flow analysis. Hydrology and Earth System Sciences 13: 595–604.
- Maloszewski P, Zuber A. 1982. Determining the turnover time of groundwater systems with the aid of environmental tracers: 1. Models and their applicability. Journal of Hydrology 57: 207–231. DOI:10.1016/0022-1694(82)90147-0.
- Maloszewski P, Rauert W, Stichler W, Herrmann A. 1983. Application of flow models in an alpine catchment area using tritium and deuterium data. Journal of Hydrology 66: 319–330.
- Maloszewski P, Zuber A. 1993. Principles and practice of calibration and validation of mathematical models for the interpretation of environmental tracer data. Advances in Water Resources 16: 173–190.
- Maloszewski P, Zuber A. 1996. Lumped parameter models for the interpretation of environmental tracer data, in Manual on Mathematical Models in Isotope Hydrogeology, TECDOC-910, Y Yurtsever (ed.). Int. At. Energy Agency: Vienna; 9–58.
- McDonnell JJ, Sivapalan M, Vaché K, Dunn SM, Grant G, Haggerty R, Hinz C, Hooper R, Kirchner J, Roderick ML, Selker J, Weiler M. 2007. Moving beyond heterogeneity and process complexity: A new vision for watershed hydrology. Water Resources Research 43: W07301.
- McGlynn B, McDonnell J, Stewart M, Seibert J. 2003. On the relationships between catchment scale and streamwater mean residence time. Hydrological Processes 17(1): 175–181.
- McGuire KJ, DeWalle DR, Gburek WJ. 2002. Evaluation of mean residence time in subsurface waters using oxygen-18 fluctuations during drought conditions in the mid- Appalachians. Journal of Hydrology 261: 132–149. DOI:10.1016/S0022-1694(02)00006-9.
- McGuire KJ, McDonnell JJ. 2006. A review and evaluation of catchment transit time modeling. Journal of Hydrology 330: 543–563.
- McGuire KJ, McDonnell JJ, Weiler M, Kendall C, Welker JM, McGlynn BL, Seibert J. 2005. The role of topography on catchment-scale water residence time. Water Resources Research. 41(5): W05002. DOI: 10.1029/2004WR00365.
- McNamara JP, Kane DL, Hinzman LD. 1997. Hydrograph separations in an Arctic watershed using mixing model and graphical techniques. Water Resources Research 33(7): 1707–1719.
- McNamara JP, Kane DL, Hinzman LD. 1998. An analysis of streamflow hydrology in the Kuparuk River Basin, Arctic Alaska: a nested watershed approach. Journal of Hydrology 206: 39–57.
- Nash JE, Sutcliffe VJ. 1970. River flow forecasting through conceptual models: I. A discussion of principles. Journal of Hydrology 10: 282–290. DOI: 10.1016/0022-1694 (70)90255-6.
10.1016/0022-1694(70)90255-6 Google Scholar
- Niemi AJ. 1977. Residence time distribution of variable flow processes. International Journal of Applied Radiation and Isotopes 28: 855–860.
- Niemi AJ. 1977. Residence time distribution of variable flow processes. International Journal of Applied Radiation and Isotopes 28: 855–860. DOI:10.1016/0020-708X(77)90026-6.
- Ottosson-Löfvenius MO, Kluge M, Lundmark T. 2003. Snow and soil frost depth in two types of shelterwood and a clear-cut area. Scandinavian Journal of Forest Research 18: 54–63.
- Peterson BJ, Holmes RM, McClelland JW, Vörösmarty CJ, Lammers RB, Shiklomanov AI, Shiklomanov IA, Rahmstor S. 2002. Increasing river discharge to the Arctic Ocean. Science 298: 2171–2173.
- Rodhe A, Nyberg L, Bishop K. 1996. Transit times for water in a small till catchment from a step shift in the oxygen 18 content of the water input. Water Resources Research 32(12): 3497–3511.
- Roulet NT, Woo MK. 1988. Runoff generation in a low arctic drainage basin. Journal of Hydrology 101: 213–226.
- Santeford HS. 1979. Toward hydrologic modeling of the black spruce/permafrost ecosystem of interior Alaska. In Proceedings 30th Alaska Science Conference. Fairbanks, Alaska.
- Sayama T, McDonnell JJ. 2009. A new time-space accounting scheme to predict stream water residence time and hydrograph source components at the watershed scale. Water Resources Research 45: W07401. DOI: 10.1029/2008WR007549.
- Seibert J, McGlynn B. 2007. A new triangular multiple flow direction algorithm for computing upslope areas from gridded digital elevation models. Water Resources Research 43: W04501. DOI: 10.1029/2006WR005128.
- Sivapalan M, Beven K, Wood EF. 1987. On hydrologic similarity. 1. A scaled model of storm runoff production:. Water Resources Research 23(11): 2266–2278.
- Slaughter CW, Kane DL. 1979. Hydrologic role of shallow organic soils in cold climates. Proceedings, Canadian Hydrology Symposium 79—Cold Climate Hydrology. National Research Council of Canada: Ottawa; 380–389.
- Soulsby C, Tetzlaff D, Dunn SM, Waldron S. 2006a. Scaling up and out in runoff process understanding—insights from nested experimental catchment studies. Hydrological Processes 20: 2461–2465.
- Soulsby C, Tetzlaff D, Rodgers P, Dunn SM, Waldron S. 2006b. Runoff processes, stream water residence times and controlling landscape characteristics in a mesoscale catchment: an initial evaluation. Journal of Hydrology 325: 197–221.
- Spence C, Woo MK. 2006. Hydrology of sub-arctic Canadian shield: heterogenous headwater basins. Journal of Hydrology 317: 138–154.
- Tetzlaff D, Malcolm IA, Soulsby C. 2007. Influence of forestry, environmental change and climatic variability on the hydrology, hydrochemistry and residence times of upland catchments. Journal of Hydrology 346: 93–111.
- Tetzlaff D, Seibert J, Soulsby C. 2009a. Inter-catchment comparison to assess the influence of topography and soils on catchment transit times in a geomorphic province; the Cairngorm mountains, Scotland. Hydrological Processes 20: 1874–1886.
- Tetzlaff D, Seibert J, McGuire KJ, Laudon H, Burns DA, Dunn SM, Soulsby C. 2009b. How does landscape structure influence catchment transit times across different geomorphic provinces? Hydrological Processes 23(6): 945–953.
- Troch PA, Carrillo GA, Heidbüchel I, Rajagopal S, Switanek M, Volkmann THM, Yaeger M. 2008. Dealing with landscape heterogeneity in watershed hydrology: a review of recent progress toward new hydrological theory. Geography Compass 2(3): 375–392.
- Troch PA, Paniconi C, van Loon E. 2003. Hillslope-storage Boussinesq model for subsurface flow and variable source areas along complex hillslopes: 1. Formulation and characteristic response. Water Resources Research 39: 1316, DOI: 10.1029/2002WR001728.
- Troch PA, van Loon E, Hilberts A. 2004. Analytical solution of the linearized hillslope-storage Boussinesq equation for exponential hillslope width functions. Water Resources Research 40: W0860. DOI: 10.1029/2003WR002850.
- Wagener T, Sivapalan M, Troch P, Woods R. 2007. Catchment classification and hydrologic similarity. Geography Compass 1: 901–931. DOI:10.1111/j.1749–8198.2007.00039.x.
10.1111/j.1749-8198.2007.00039.x Google Scholar
- Woo MK, Kane DL, Carey SK, Yang D. 2008. Progress in permafrost hydrology in the new millennium. Permafrost and Periglacial Processes 19: 237–254.
- Yamazaki Y, Kubota J, Ohata T, Vuglinsky V, Mizuyama T. 2006. Seasonal changes in runoff characteristics on a permafrost watershed in the southern mountainous region of eastern Siberia. Hydrological Processes 20: 453–467.
- Yurtsever Y, Payne B. 1986. Mathematical models based on compartmental simulation approach for quantitative interpretation of tracer data in hydrological systems. In 5th International Symposium on Underground Water Tracers, A Morif, P Paraskevopoulou (eds). A.A. Balkema: Vermont, USA; 341–353.
