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9 - Snowmelt-runoff processes

Published online by Cambridge University Press:  18 August 2009

David R. DeWalle  and
Albert Rango
David R. DeWalle
Affiliation:
Pennsylvania State University
Albert Rango
Affiliation:
New Mexico State University
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Principles of Snow Hydrology , pp. 235 - 265
Publisher: Cambridge University Press
Print publication year: 2008

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References

Aizen, V. B., Aizen, E. M., and Melack, J. M. (1995). Climate, snow cover, glaciers, and runoff in the Tien Shan, Central Asia. Water Resour. Bull., 31(6), 1113–29.CrossRefGoogle Scholar
Aizen, V. B., Aizen, E. M., and Melack, J. M. (1996). Precipitation, melt and runoff in the northern Tien Shan. J. Hydrol., 186, 229–51.CrossRefGoogle Scholar
Aldrich, H. P. Jr. (1956). Frost penetration below highway and airfield pavements. Highway Res. Board, 135, 124–44.Google Scholar
Anderson, E. A. (1973). National Weather Service River Forecast System – Snow Accumulation and Ablation Model. NWS Hydro-17. US Dept. Commerce, NOAA, National Weather Service.Google Scholar
Anderson, E. and Larson, L. (1996). The role of snowmelt in the January 1996 floods in the Northeastern United States. In Proceedings of the 53rd Annual Meeting, Eastern Snow Conf., pp. 141–9.Google Scholar
Bathurst, J. C. and Cooley, K. R. (1996). Use of SHE hydrological modelling system to investigate basin response to snowmelt at Reynolds Creek, Idaho. J. Hydrol., 175, 181–211.CrossRefGoogle Scholar
Bengtsson, L. and Westerstrom, W. (1992). Urban snowmelt and runoff in northern Sweden. Hydrol. Sci., 37, 263–75.CrossRefGoogle Scholar
Bengtsson, L., Seuna, P., Lepisto, A., and Saxena, R. K. (1992). Particle movement of melt water in a subdrained agricultural basin. J. Hydrol., 135, 383–98.CrossRefGoogle Scholar
Berris, S. N. and Harr, R. D. (1987). Comparative snow accumulation and melt during rainfall in forested and clear-cut plots in the Western Cascades of Oregon. Water Resour. Res., 23(1), 135–42.CrossRefGoogle Scholar
Buttle, J. M. (1994). Isotope hydrograph separations and rapid delivery of pre-event water from drainage basins. Prog. Phys. Geog., 18(1), 16–41.CrossRefGoogle Scholar
Caine, N. (1992). Modulation of the diurnal streamflow response by the seasonal snowcover of an alpine basin. J. Hydrol., 137, 245–60.CrossRefGoogle Scholar
Carey, S. K. and Woo, M. (1998). Snowmelt hydrology of two subarctic slopes, Southern Yukon, Canada. Nordic Hydrol., 29(4/5), 331–46.CrossRefGoogle Scholar
Cline, D. W. (1997). Snow surface energy exchanges and snowmelt at a continental, midlatitude Alpine site. Water Resour. Res., 33(4), 689–701.CrossRefGoogle Scholar
Cooley, K. R. and Palmer, P. (1997). Characteristics of snowmelt from NRCS SNOTEL (SNOwTELemetry) sites. Proceedings of the 65th Annual Western Snow Conference, Banff, Alberta, Canada, pp. 1–11.Google Scholar
DeGaetano, A. T., Wilks, D. S., and McKay, M. (1996). A physically based model of soil freezing in humid climates using air temperature and snow cover data. J. Appl. Meteorol., 35, 1009–27.2.0.CO;2>CrossRefGoogle Scholar
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, 232(2), 565–71.CrossRefGoogle Scholar
Garstka, W. U., Love, L. D., Goodell, B. C., and Bertle, F. A. (1958). Factors Affecting Snowmelt and Streamflow: a Report on the 1946–1953 Cooperative Snow Investigations at the Fraser Experimental Forest, Fraser, Colorado. US Bureau of Reclamation, US Forest Service, US Government Printing Office.Google Scholar
Gibson, J. J., Edwards, T. W. D., and Prowse, T. D. (1993). Runoff generation in a high boreal wetland in northern Canada. Nordic Hydrol., 24, 213–24.CrossRefGoogle Scholar
Hardy, J. P. and Albert, M. R.. (1995). Snow-induced thermal variations around a single conifer tree. In Proceedings of the 52nd Eastern Snow Conference, Toronto, Ontario, Canada: June 7–8, 1995, pp. 239–47.Google Scholar
Harr, R. D. (1986). Effects of clearcutting on rain-on-snow runoff in Western Oregon: a new look at old studies. Water Resour. Res., 22(7), 1095–100.CrossRefGoogle Scholar
Hinzman, L. D. and Kane, D. L.. (1991). Snow hydrology of a headwater Arctic basin 2. Conceptual analysis and computer modeling. Water Resour. Res., 27, 1111–21.CrossRefGoogle Scholar
Kane, D. L. and Stein, J. (1983). Water movement into seasonally frozen soils. Water Resour. Res., 19(6), 1547–57.CrossRefGoogle Scholar
Kattleman, R. (1997). Flooding from rain-on-snow events in the Sierra Nevada. In Destructive Water: Water-Caused Natural Disasters, their Abatement and Control, Conference Proceedings, IAHS Publ. No. 239, Anaheim, CA, June 1966, pp. 59–65.Google Scholar
Kattleman, R., Berg, N., and McGurk, B. (1991). A history of rain-on-snow floods in the Sierra Nevada., In Proceedings of the 59th Western Snow Conference, Juneau, Alaska April 13–15, 1991, pp. 138–41.Google Scholar
Kersten, M. (1949). Thermal properties of soils. University of Minnesota, Engin. Exp. Sta. Bulletin, 28.Google Scholar
Kendall, K. A., Shanley, J. B., and McDonnell, J. J. (1999). A hydrometric and geochemical approach to test the transmissivity feedback hypothesis during snowmelt. J. Hydrol., 219, 188–205.CrossRefGoogle Scholar
Kuchment, L. S. (1997). Estimating the risk of rainfall and snowmelt disastrous floods using physically-based models of river runoff generation. In Destructive Water: Water Caused Natural Disasters, Their Abatement and Control, Conference Proceedings, IAHS Publ. 239, Anaheim, CA, pp. 95–100.Google Scholar
Leydecker, A. and Melack, J. M. (1999). Evaporation from snow in the Central Sierra Nevada of California. Nordic Hydrol., 30(2), 81–108.CrossRefGoogle Scholar
Lewis, T., Braun, C., Hardy, D. R., Francus, P., and Bradley, R. S.. (2005). An extreme sediment transfer event in a Candadian high Arctic stream. Arct., Antarct. Alp. Res., 37, 477–82.CrossRefGoogle Scholar
Lundquist, J. D., Dettinger, M. D. and Cayan, D. R. (2005). Snow-fed streamflow timing at different basin scales: Case study of the Tuolumne River above Hetch Hetchy, Yosemite, California. Water Resour. Res., 41(W07005), 1–14.CrossRefGoogle Scholar
MacDonald, L. H. and Hoffman, J. A. (1995). Causes of peak flows in Northwestern Montana and Northeastern Idaho. Water Resour. Bull., 31(l), 79–95.CrossRefGoogle Scholar
Marks, D., Kimball, J., Tingey, D., and Link, T. (1998). The sensitivity of snowmelt processes to climate conditions and forest cover during rain-on-snow: a case study of the 1996 Pacific Northwest flood. Hydrol. Processes, 12, 1569–87.3.0.CO;2-L>CrossRefGoogle Scholar
Marsh, P. (1999). Snowcover formation and melt: recent advances and future prospects. Hydrol. Processes, 13, 2117–34.3.0.CO;2-9>CrossRefGoogle Scholar
McNamara, J. P., Kane, D. L. and Hinzman, L. D.. (1997). Hydrograph separation in an Arctic watershed using mixing model and graphical techniques. Water Resour. Res., 33, 1707–19.CrossRefGoogle Scholar
Moore, R. D. (1993). Application of a conceptual streamflow model in a glacierized drainage basin. J. Hydrol., 150, 151–68.CrossRefGoogle Scholar
Persson, M. (1976). Hydrologiska undersokningar i Lapptraskets representativa omrade (In Swedish, English title: Hydrological Studies in the Lapptrasket Representative Catchment), SMHI HB Rapport no. 13, Norrkoping, Sweden: Swedish Meteorol. and Hydrol. Instit.Google Scholar
Prévost, M., Barry, R., Stein, J., and Plamondon, A. P. (1990). Snowmelt runoff modelling in a balsam fir forest with a variable source area simulator (VSAS2). Water Resour. Res., 26(5), 1067–77.CrossRefGoogle Scholar
Rekolainen, S. and Posch, M. (1993). Adapting the CREAMS model for Finnish conditions. Nordic Hydrol., 24, 309–22.CrossRefGoogle Scholar
Rodhe, A. (1998). Chapter 12: Snowmelt dominated systems. In Isotope Tracers in Catchment Hydrology, ed. Kendall, B. V. C. and McDonnell, J. J., Amsterdam: Elsevier, pp. 391–433.Google Scholar
Semadeni-Davies, A. (1998). Modelling snowmelt induced waste water inflows. Nordic Hydrol., 29(4/5), 285–302.CrossRefGoogle Scholar
Schmidt, R. A., Troendle, C. A., and Meiman, J. R.. (1998). Sublimation of snowpacks in subalpine conifer forests. Can. J. For. Res., 28, 501–13.CrossRefGoogle Scholar
Shanley, J. B. and Chalmers, A. (1999). The effect of frozen soil on snowmelt runoff at Sleepers River, Vermont. Hydrol. Processes, 13, 1843–57.3.0.CO;2-G>CrossRefGoogle Scholar
Shutov, V. A. (1993). Calculation of snowmelt. Russian Meteorol. and Hydrol., 4, 14–20.Google Scholar
Stadler, D., Wunderli, H., Auckenthaler, A., Flühler, H., and Bründl, M. (1996). Measurement of frost-induced snowmelt runoff in a forest soil. Hydrol. Process., 10, 1293–1304.3.0.CO;2-I>CrossRefGoogle Scholar
Todhunter, P. E. (2001). A hydroclimatological analysis of the Red River of the North snowmelt flood catastrophe of 1997. J. Amer. Water Resour. Assoc., 37, 1263–78.CrossRefGoogle Scholar
US Army Corps of Engineers (1956). Snow Hydrology: Summary Report of the Snow Investigations. Portland, OR: North Pacific Div., US Army Corps of Engineers.
Westmacott, J. R. and Burn, D. H. (1997). Climate change effects on the hydrologic regime within the Churchill-Nelson River Basin. J. Hydrol., 202, 263–79.CrossRefGoogle Scholar
Woo, M.-K. (1986). Permafrost hydrology in North America. Atmos. Ocean, 24(3), 201–234.CrossRefGoogle Scholar
Woo, M.-K. (1983). Hydrology of a drainage basin in the Canadian high Arctic. Annals Assoc. Amer. Geogr., 73, 577–596.CrossRefGoogle Scholar
Woo, M.-K. and J. Sauriol. (1980). Channel development in snow-filled valleys, Resolute, N. W. T., Canada. Geogr. Ann., 62A, 37–56.
Zhang, Z., Kane, D. L., and Hinzman, L. D.. (2000). Development and application of a spatially-distributed Arctic hydrological and thermal process model (ARHYTHM). Hydrol. Processes, 14, 1017–44.3.0.CO;2-G>CrossRefGoogle Scholar
Zhao, L. and Gray, D. M. (1999). Estimating snowmelt infiltration into frozen soils. Hydrol. Processes, 13, 1827–42.3.0.CO;2-D>CrossRefGoogle Scholar
Zhenniang, Y., Fungzian, L., Zhihuai, Y., and Qiang, W. (1994). The effect of water and heat on hydrological processes of a high alpine permafrost area. In Snow and Ice Covers: Interactions with the Atmosphere and Ecosystems, IAHS Publ. 223, ed. Jones, E. G., Davies, T. D., Ohmura, A., and Morris, E. M., pp. 259–68.Google Scholar

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