Simple Snowdrift Model for Distributed Hydrological Modeling
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Volume 9, Issue 4
Abstract
A simple snowdrift model was developed, incorporated into a distributed winter-time hydrological model, and tested against snow measurements from a hillside in eastern Washington State. Snow movement can be an important factor in the distribution of spring soil moisture and runoff. Although current hydrological models often attempt to account for heterogeneities in precipitation distribution, they do not account for snowdrift. Snow melts and accumulates during the same times that it is redistributed. Therefore, evaluation required a snowmelt/accumulation model to be coupled with the snowdrift model. The snowmelt/accumulation model used the standard energy balance approach and performed well, i.e., standard errors of snow water equivalent ≈1 cm. The snowdrift model’s simulated snow distribution generally agreed with observed snow distribution across a hill. Most notable were the model’s ability to correctly place a snowdrift on the lee side of the hill and its ability to predict snow removal from nondrift areas. The effects of snow redistribution and the model’s ability to reproduce these were obvious when overlaid on model results that ignored snowdrift.
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References
Abbott, M. B., Bathurst, J. C., Cunge, J. A., O’Connell, P. E., and Rasmussen, J.(1986). “An introduction to the European hydrological system—Systeme hydrologique Europeen, ‘SHE’.” J. Hydrol., 87, 45–59.
Ambroise, B., Freer, F., and Beven, K.(1996). “Application of a generalized TOPMODEL to a small Ringelbach catchment, Vosges, France.” Water Resour. Res., 32(7), 2147–2159.
Anderson, E. A. (1976). “A point energy and mass balance model of snow cover.” NOAA Technical Rep. NWS 19, U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, National Weather Service. Washington, D.C.
Anderson, E. A., and Whipkey, R. Z. (1977). “NOAA-ARS cooperative snow research project, watershed hydroclimatology and data for water years 1960–1974.” U.S. Dept. of Commerce and U.S. Dept. of Agriculture, Washington, D.C.
Barry, R. M., Prevost, M., Stein, J., and Plamondon, A.(1990). “Application of a snow cover energy and mass balance model in a balsam fir forest.” Water Resour. Res., 26(5), 1079–1092.
Bengtsson, L.(1980). “Evaporation from a snow cover.” Nord. Hydrol., 11(5), 221–234.
Bristow, K. L., and Campbell, G. S.(1984). “On the relationship between incoming solar radiation and daily maximum and minimum temperature.” Agric. Forest Meteorol., 31(2), 159–166.
Brooks, E. S. (1997). “The spatial and temporal variability of a frozen soil layer in a heterogeneous landscape.” MS thesis, Dept. of Biosystems and Agricultural Engineering, Univ. of Minnesota, Twin Cities, Minn.
Campbell, G. S. (1977). An introduction to environmental biophysics, Springer, New York.
Cazorzi, F., and Fontana, G. D.(1996). “Snowmelt modeling by combining air temperature and a distributed radiation index.” J. Hydrol., 181(1/4), 169–187.
Dunne, T. (1998). “Wolman Lecture: Hydrologic science…in landscapes…on a planet…in the future.” Proc., 1997 Abel Wolman Distinglished Lecture and Symp. on Hydrologic Sciences, National Academy Press, Washington, D.C., 1–9.
Flerchinger, G. N., and Saxton, K. E.(1989). “Simultaneous heat and water model of a freezing snow-residue-soil system I: Theory and development.” Trans. ASAE, 32(2), 565–571.
Flerchinger, G. N., Shang, S. L., and Finnie, F. I.(1996). “Simulatingthree-dimensional ground water response in a small mountainous watershed.” Water Resour. Bull., 32(5), 1081–1088.
Frankenberger, J. R., Brooks, E. S., Walter, M. T., Steenhuis, T. S., and Walter, M. F.(1999). “A GIS-based variable source area hydrological model.” Hydrolog. Process., 13(6), 805–822.
Gauer, P.(2001). “Numerical modeling of blowing and drifting snow in Alpine terrain.” J. Glaciol., 47(156), 97–110.
Goodison, B. E., Ferguson, H. L., and McKay, G. A. (1981). Measurement and data analysis handbook, D. M. Gray and D. H. Male, eds., Pergamon, Tarrytown, N.Y., 191–274.
Grant, R. F.(1992). “Dynamic simulation of phase changes in snowpacks and soils.” Soil Sci. Soc. Am. J., 56(4), 1051–1062.
Grayson, R. B., Moore, I. D., and McMahon, T. A.(1992). “Physically based hydrological modeling 2: Is the concept realistic?” Water Resour. Res., 26(10), 2659–2666.
Holko, L., and Lepisto, A.(1997). “Modeling the hydrological behavior of a mountain catchment using TOPMODEL.” J. Hydrol., 196(1/4), 361–377.
Hottelet, C., Braun, L. N., Leibundgut, C., and Rieg, A.(1993). “Simulation of snowpack and discharge in an Alpine karst basin.” LAHS Publ., 218, 249–260.
Jensen, M. E., Burman, R. D., and Allen, R. G. eds. (1990). Evapotranspiration and irrigation water requirements, ASCE, New York.
Kind, R. J. (1981). “Snow drifting.” Handbook of snow, D. M. Gray and D. H. Male, eds., Pergamon, Tarrytown, N.Y., 338–359.
Kustas, W. P., Rango, A., and Uijlenhoet, R.(1994). “A simple energy budget algorithm for the snowmelt runoff model.” Water Resour. Res., 30(5), 1515–1527.
Lehning, M., Doorschot, J., and Bartelt, P.(2000). “A snowdrift index based on SNOWPACK model calculations.” Ann. Glaciol., 31, 382–386.
Lindstrom, G., Johansson, B., Persson, M., Gardelin, M., and Bergstrom, S.(1997). “Development and test of the distributed HBV-96 hydrological model.” J. Hydrol., 201(1/4), 272–288.
Liston, G. E., and Sturm, M. A.(1998). “A snow-transport model for complex terrain.” J. Glaciol., 44(148), 498–516.
Lykossov, V. N. (2001). “Numerical modelling of interaction between the atmospheric boundary layer and the Antarctic ice shelf.” Russ. J. Numer. Anal. Math. Model., 16(4), 315–330.
Marks, D., Domingo, J., Susong, D., Link, T., and Garen, D.(1999). “A spatially distributed energy balance snowmelt model for application in mountain basins.” Hydrolog. Process., 13(12–13), 1935–1959.
Marks, D., Link, T., Winstral, A., and Garen, D.(2001). “Simulating snowmelt processes during rain-on-snow over a semi-arid mountain basin.” Ann. Glaciol., 32, 195–202.
McConkey, B. G. (1992). “Modeling cold region agricultural hillslope hydrology.” PhD thesis, Dept. of Crop and Soil Sciences, Washington State Univ., Pullman, Wash.
Ndlovu, L. S. (1994). “Weather data generation and its use in estimating evapotranspiration.” PhD Thesis, Engineering Science, Biosystems Engineering Dept., Washington State Univ., Pullman, Wash.
Ogden, F. L., and Julien, P. Y.(1993). “Runoff sensitivity to temporal and spatial rainfall variability at runoff plane and small basin scales.” Water Resour. Res., 29(8), 2589–2597.
O’Neil, A. D. J., and Gray, D. M. (1973). “Spatial and temporal variations of the albedo of prairie snowpack.” The role of snow and ice in hydrology, Proc., Banff Symp., Unesco-WMO-IAHS, Vol. 1, Paris, 176–186.
Pomeroy, J. W., and Gray, D. M.(1990). “Saltation of snow.” Water Resour. Res., 26(7), 1583–1594.
Pomeroy, J. W., Gray, D. M., and Landine, P. G.(1993). “The prairie blowing snow model—Characteristics, validations, operation.” J. Hydrol., 144(1–4), 165–192.
Pomeroy, J. W., and Li, L.(2000). “Prairie and arctic areal snow cover mass balance using a blowing snow model.” J. Geophys. Res., [Atmos.], 105(D21), 26619–26634.
Pomeroy, J. W., Marsh, P., and Gray, D. M.(1997). “Application of a distributed blowing snow model to the arctic.” Hydrolog. Process., 11(11), 1451–1464.
Rango, A., and Martinec, J.(1995). “Revisiting the degree-day method for snowmelt computations.” Water Resour. Bull., 31(4), 657–669.
Schmidt, R. A., Jr. (1972). “Sublimation of wind-transported snow—A model.” USDA Forest Service Research Paper RM, U.S. Rocky Mountain Forest and Range Experiment Station, U.S. Dept. of Agriculture, Washington, D.C.
Schreider, S. T., Whetton, P. H., Jakeman, A. J., and Pittock, A. B.(1997). “Runoff modelling for snow-affected catchments in the Australian alpine region, eastern Victoria.” J. Hydrol., 200(1/4), 1–23.
Schroeter, H. O., and Whitely, H. R. (1987). “SAAM—An operational snow accumulation-ablation model for aerial distribution of shallow ephemeral snowpacks.” Proc., Canadian Society of Civil Engineers Conf., Quebec, 482–500.
Sivardiere, F., Castelle, T., Guyomarch, G., Merindol, L., and Buisson, L.(1995). “Functioning of the avalanche starting zones which undergo snow transport by wind—Field observations and computer modeling.” Surv. Geophys., 16(5–6), 729–741.
Steppuhn, H. (1981). “Snow and agriculture.” Handbook of snow, D. M. Gray and D. H. Male., eds, Pergamon, Tarrytown, N.Y., 60–125.
Steppuhn, H., and McConkey, B. G. (1988). “Design capacities for snowcover retention in grain stubble.” Paper No. 88-301. Canadian Society of Agricultural Engineers, Ottawa.
Stull, R. B. (1988). An introduction to boundary layer meteorology, Kluwer Academic, Dordrecht, The Netherlands.
Tabler, R. D. (1975). “Estimating the transport and evaporation of blowing snow.” Proc., Symp. on Snow Management in the Great Plains, Great Plains Agricultural Council, Rapid City, S.D., 73, 85–104.
Tuteja, N. K., and Cunnane, C.(1997). “Modeling coupled transport of mass and energy into the snowpack—Model development, validations, and sensitivity analysis.” J. Hydrol., 195(1/4), 232–255.
Unsworth, M. H., and Monteith, L. J.(1975). “Long-wave radiation at the ground. I. Angular distribution of incoming radiation.” Q. J. R. Meteorol. Soc., 101(427), 13–24.
U.S. Army Corps of Engineers (USACE). (1960). Runoff from snowmelt, EM 1110-2-1406:68, U.S. Government Printing Office, Washington, D.C.
Walter, M. T. (1995). “Winter-time hydrologic modeling over a three-dimensional landscape.” PhD thesis, Engineering Science, Biosystems Engineering Dept., Washington State University, Pullman, Wash.
Wigmosta, M. S., and Burges, S. J.(1997). “An adaptive modeling and monitoring approach to describe the hydrologic behavior or small catchments.” J. Hydrol., 30(6), 1665–1679.
Wigmosta, M. S., Vail, L. W., and Lettenmaier, D. P.(1994). “A distributed hydrology-vegetation model for complex terrain.” Water Resour. Res., 30(6), 1665–1679.
Wood, E. F. (1998). “Hydrologic measurements and observations: An assessment of needs.” Proc., 1997 Abel Wolman Distinglished Lecture and Symposium on Hydrologic Sciences, National Academy Press, Washington, D.C., 67–86.
Young, R. A., Onstad, C. A., Bosch, D. D., and Anderson, W. P.(1989). “AGNPS: A nonpoint-source pollution model for evaluating agricultural watersheds.” J. Soil Water Conservat., 44(2), 168–173.
Zollweg, J. A., Gburek, W. J., and Steenhuis, T. S.(1996). “SMoRMod—a GIS-integrated rainfall-runoff model.” Trans. ASAE, 39(4), 1299–1307.
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Published In
Journal of Hydrologic Engineering
Volume 9 • Issue 4 • July 2004
Pages: 280 - 287
Copyright
Copyright © 2004 American Society of Civil Engineers.
History
Received: Mar 25, 2002
Accepted: Nov 10, 2003
Published online: Jun 15, 2004
Published in print: Jul 2004
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