[Avanzi, F., Caruso, M., Jommi, C., De Michele, C., Ghezzi, A., 2014. Continuous-time monitoring of liquid water content in snowpacks using capacitance probes: A preliminary feasibility study. Advances in Water Resources, 68, 32–41.10.1016/j.advwatres.2014.02.012]Search in Google Scholar
[Avanzi, F., Yamaguchi, S., Hirashima, H., De Michele, C., 2015. Bulk volumetric liquid water content in a seasonal snowpack: modeling its dynamics in different climatic conditions. Advances in Water Resources, 86, 1–13.10.1016/j.advwatres.2015.09.021]Search in Google Scholar
[Balk, B., Elder, K., 2000. Combining binary decision and geostatistical methods to estimate snow distribution in a mountain watershed. Water Resources Research, 36, 1, 13–26.10.1029/1999WR900251]Search in Google Scholar
[Blöschl, G., Kirnbauer, R., 1991. Point snowmelt models with different degrees of complexity - internal processes. Journal of Hydrology, 129, 127–147.10.1016/0022-1694(91)90048-M]Search in Google Scholar
[Danko, M., Krajčí, P., Hlavčo, J., 2014. Vzťah výšky snehovej pokrývky a vodnej hodnoty snehu v lese a na voľnej ploche v povodí Jaloveckého potoka. [The relationship between snow depth and snow water equivalent in the forest and in the open area in the Jalovecký creek catchment]. Acta Hydrologica Slovaca, 15, 1, 116–128. (In Slovak.)]Search in Google Scholar
[De Michele, C., Avanzi, F., Passoni, D., Barzaghi, R., Pinto, L., Dosso, P., Ghezzi, A., Gianatti, R., Della Vedova, G., 2016. Using a fixed-wing UAS to map snow depth distribution: an evaluation at peak accumulation. The Cryosphere, 10, 511–522. doi:10.5194/tc-10-511-2016.10.5194/tc-10-511-2016]Search in Google Scholar
[DeWalle, D.R., Rango, A., 2008. Principles of Snow Hydrology. Cambridge University Press, Cambridge.10.1017/CBO9780511535673]Search in Google Scholar
[Elder, K., Marshall, H. P., Elder, L., Starr, B., Karlson, A., Robertson, J., 2014. Design and installation of a tipping bucket snow lysimeter. In: Proc. Int. Snow Science Workshop, ISSW steering committee, Banff, pp. 817–824.]Search in Google Scholar
[Gray, D.M., 1979. Snow accumulation and distribution. In: Colbeck, S.C., Ray, M. (Eds.): Proc. Modeling of snow cover runoff, J. S. Army Cold Regions Research and Engineering Laboratory, Hanover, N.H., pp. 3–33.]Search in Google Scholar
[Greenan, H.J., Anderson, E.A., 1984. A snowmelt lysimeter for research applications. In: Elhadi, N.D., Frechette, M.A. (Eds.): Proc. 41 Annual Eastern Snow Conference, Eastern Snow Conference, Washington, D.C., pp. 212–216.]Search in Google Scholar
[Grünewald, T., Schirmer, M., Mott, R., Lehning, M., 2010. Spatial and temporal variability of snow depth and SWE in a small mountain catchment. Cryosphere, 4, 1–11.10.5194/tcd-4-1-2010]Search in Google Scholar
[Haupt, H.F., 1969. A simple snowmelt lysimeter. Water Resources Research, 5, 3, 714–718.10.1029/WR005i003p00714]Search in Google Scholar
[Heilig, A., Mitterer, C., Schmid, L., Wever, N., Schweizer, J., Marshall, H.P., Eisen, O., 2015. Seasonal and diurnal cycles of liquid water in snow – Measurements and modeling. J. Geophysical Research Earth Surface, http://dx.doi.org/10.1002/2015JF003593]Search in Google Scholar
[Herrmann, A., 1978. A recording snow lysimeter. Journal of Glaciology, 20, 82, 209–213.10.3189/S0022143000198107]Search in Google Scholar
[Hirashima, H., Yamaguchi, S., Katsushima, T., 2014. A multidimensional water transport model to reproduce preferential flow in the snowpack. Cold Regions Sci. Technol., 108, 80–90. http://dx.doi.org/10.1016/j.coldregions.2014.09.004]Search in Google Scholar
[Hlavčová, K., Kotríková, K., Kohnová, S., Valent, P., 2015. Changes in the snow water equivalent in mountainous basins in slovakia over recent decades. IAHS Publ. No. 370, IAHS Press, Wallingford, pp. 109–116.10.5194/piahs-370-109-2015]Search in Google Scholar
[Hock, R., 2003. Temperature index melt modelling in mountain areas. J. Hydrol., 282, 104–115. doi: 10.1016/S0022-1694(03)00257-9.10.1016/S0022-1694(03)00257-9]Search in Google Scholar
[Holko, L., Kostka, Z., 2008. Hydrological characteristics of snow cover in the Western Tatra Mountains in winters 1987–2008. Folia Geographica, Series Geographica-Physica, vol. XXXIX, 63–77.]Search in Google Scholar
[Holko, L., Kostka, Z., Parajka, J., 2003. Distributed snow water equivalent modeling in a mountain catchment. Journal of Hydrology and Hydromechanics, 51, 1, 39–51.]Search in Google Scholar
[Holko, L., Sokratov, S.A., Shmakin, A.B., Kostka, Z., 2009a. Simulation of snow water equivalent by mathematical models of different complexity. Materialy Glyatsiologicheskikh Issledovanii, no. 107, 72–80. ISSN 0145 8752.]Search in Google Scholar
[Holko, L., Škvarenina, J., Kostka, Z., Frič, M., Staroň, J., 2009b. Impact of spruce forest on rainfall interception and seasonal snow cover evolution in the Western Tatra Mountains, Slovakia. Biologia 64, 3, 594–599. doi: 10.2478/s11756-009-0087-6.10.2478/s11756-009-0087-6]Search in Google Scholar
[Holko, L., Gorbachova, L., Kostka, Z., 2011. Snow Hydrology in Central Europe. Geography Compass, 5, 4, 200–218. doi: 10.1111/j.1749-8198.2011.00412.x.10.1111/j.1749-8198.2011.00412.x]Search in Google Scholar
[Holko, L., Danko, M., Kostka, Z., 2012. Klasifikácia zím, hustota nového snehu a teplotný faktor topenia snehovej pokrývky v povodí Jaloveckého potoka. [Classification of winters, density of new snow and the degree-day factor in the Jalovecký creek catchment]. Acta Hydrologica Slovaca, 13, 2, 342–349. (In Slovak.)]Search in Google Scholar
[Holko, L., Danko, M., Dóša, M., Kostka, Z., Šanda, M., Pfister, L., Iffly, J.F., 2013. Spatial and temporal variability of stable water isotopes in snow related hydrological processes. Die Bodenkultur, 64, 3–4, 39–45.]Search in Google Scholar
[Hríbik, M., Vida, T., Škvarenina, J., Škvareninová, J. Ivan, Ľ., 2012. Hydrological effects of Norway spruce and European beech on snow cover in a mid-mountainous region of the Poľana Mts., Slovakia. J. Hydrol. Hydromech., 60, 2012, 4, 319–332. doi: 10.2478/v10098-012-0028-x.10.2478/v10098-012-0028-x]Search in Google Scholar
[Kattelmann, R.C., 1984. Snowmelt lysimeters: design and use. In: Proc. 52nd Annual Meeting of the Western Snow Conference, Western Snow Conference, Sun Valley, ID, pp. 68–79.]Search in Google Scholar
[Khan, V., Holko, L., 2009. Snow cover characteristics in the Aral Sea Basin from different data sources and their relation with river runoff. Journal of Marine Systems, 76, 254–262.10.1016/j.jmarsys.2008.03.012]Search in Google Scholar
[Kinar, N.J., Pomeroy, J.W., 2015. SAS2: the system for acoustic sensing of snow. Hydrol. Process., 29, 4032–4050.10.1002/hyp.10535]Search in Google Scholar
[Kirnbauer, R., Blöschl, G., 1990. A lysimetric snow pillow station at Kühtai/Tyrol. IAHS Publ. no. 193. IAHS Press, Wallingford, pp. 173–180.]Search in Google Scholar
[Kormos, P., Marks, D., Williams, C.J., Marshall, H.P., Aishlin, P., Chandler, D.G., McNamara, J.P., 2014. Soil, snow, subsurface storage data set from a mountain catchment in the rain–snow transition zone. Earth Systems Science Data, 6, 165–173. doi:10.5194/essd-6-165-2014.10.5194/essd-6-165-2014]Search in Google Scholar
[Kostka, Z., Holko, L., 2000. Impact of climate change on runoff in a small mountain catchment. National Climatic Program of Slovak Republic, 8. Bratislava, pp. 91–109. (In Slovak.)]Search in Google Scholar
[Kotríková, K., Hlavčová, K., Fencík, R., 2014. Changes in Snow Storage in the Upper Hron River Basin (Slovakia). Acta Silvatica et Lignaria Hungarica, 10, 2, 145–459.10.2478/aslh-2014-0011]Search in Google Scholar
[Krajčí, P., Holko, L., Perdigão, R.A.P., Parajka, J., 2014. Estimation of regional snowline elevation (RSLE) from MODIS images for seasonally snow covered mountain basins. Journal of Hydrology, 519, Part B, 1769–1778.10.1016/j.jhydrol.2014.08.064]Search in Google Scholar
[Kuusisto, E., 1980. On the values and variability of degree-day melting factors in Finland. Nord. Hydrol., 11, 5, 235–242.10.2166/nh.1980.0011]Search in Google Scholar
[Kuusisto, E., 1984. Snow accumulation and snowmelt in Finland. Publications of the Water Research Institute, National Board of Waters, Helsinki, Finland, 55, 149 p.]Search in Google Scholar
[Lehning, M., Völksch, I., Gustavson, D., Nguyen, T.A., Stähli, M., Zappa, M., 2006. ALPINE3D: A detailed model of mountain surface processes and its application to snow hydrology. Hydrol. Process., 20, 2111–2128.10.1002/hyp.6204]Search in Google Scholar
[Lehning, M., Löwe, H., Ryser, M., Raderschall, N., 2008. Inhomogeneous precipitation distribution and snow transport in steep terrain. Water Resour. Res., 44, W07404. doi: 10.1029/2007WR006545.10.1029/2007WR006545]Search in Google Scholar
[Liston, G.E, Sturm, M., 1998. A snow-transport model for complex terrain. Journal of Glaciology, 44, 148, 498–516.10.1017/S0022143000002021]Search in Google Scholar
[López-Moreno, J.I., Fassnacht, S.R., Heath, J.T., Musselman, K.N., Revuelto, J., Latron, J., Morán-Tejeda, E., Jonas, T., 2013. Small scale spatial variability of snow density and depth over complex alpine terrain: Implications for estimating snow water equivalent. Adv. Water Resour., 55, 40–52.10.1016/j.advwatres.2012.08.010]Search in Google Scholar
[Lundquist, J.D., Lott, F., 2008. Using inexpensive temperature sensors to monitor the duration and heterogeneity of snow-covered areas, Water Resour. Res., 44, W00D16, doi: 10.1029/2008WR007035.10.1029/2008WR007035]Search in Google Scholar
[Martinec, J., 1987. Meltwater percolation through an alpine snowpack In: Proc. Symp. Avalanche formation, movement and effects. IAHS Publ. No. 162. IAHS Press, Wallingford, pp. 255–264.]Search in Google Scholar
[Merz, R., Blöschl, G., 2003. Regional flood risks – what are the driving processes? IAHS Publication No. 281, IAHS Press, Wallingford, pp. 49–58.]Search in Google Scholar
[Mészároš, I., Miklánek, P., 2006. Calculation of potential evapotranspiration based on solar radiation income modeling in mountainous areas. Biologia, 61, Special Issue 19, S284–S288.10.2478/s11756-006-0174-x]Search in Google Scholar
[MIKE SHE, 2011. An integrated hydrological modelling framework, Volume 2, Reference manual, DHI, Danmark.]Search in Google Scholar
[Mott, R., Schirmer, M., Bavay, M., Grünewald, T., Lehning, M., 2010. Understanding snow-transport processes shaping the mountain snow-cover. Cryosphere, 4, 545–559.10.5194/tc-4-545-2010]Search in Google Scholar
[Nester, T., Kirnbauer, R., Parajka, J., Blöschl, G., 2012. Evaluating the snow component of a flood forecasting model. Hydrology Research, 43, 762–779.10.2166/nh.2012.041]Search in Google Scholar
[Parajka, J., Holko, L., Kostka, Z., Blöschl, G., 2012. MODIS snow cover mapping accuracy in a small mountain catchment – comparison between open and forest sites. Hydrol. Earth Syst. Sci., 16, 2365–2377, doi: 10.5194/hess-16-2365-2012.10.5194/hess-16-2365-2012]Search in Google Scholar
[Pekárová, P., Halmová, D., 2009. Snow water equivalent measurement and simulation in microbasins with different vegetation cover. Journal of Hydrology and Hydromechanics, 57, 2, 88–99.10.2478/v10098-009-0008-y]Search in Google Scholar
[Penna, D.D., Ahmad, M., Birks, S.J., Bouchaou, L., Brenčič, M., Butt, S., Holko, L., Jeelani, G., Martínez, D.E., Melikadze, G., Shanley, J.B., Sokratov, S.A., Stadnyk, T., Sugimoto, A., Vreča, P., 2014. A new method of snowmelt sampling for water stable isotopes. Hydrol. Process., 28, 22, 5637–5644. doi: 10.1002/hyp.10273.10.1002/hyp.10273]Search in Google Scholar
[Pomeroy, J.W., Brun., E., 2001. Physical properties of snow In: Jones, H.G., Pomeroy, J.W., Walker, D.A., Hoham, R.W. (Eds.): Snow Ecology: an Interdisciplinary Examination of Snow-covered Ecosystems. Cambridge University Press, Cambridge, UK., pp. 45–118.]Search in Google Scholar
[Prokop, A., 2008. Assessing the applicability of terrestrial laser scanning for spatial snow depth measurements, Cold Regions Science and Technology, 54, 3, 155–163.10.1016/j.coldregions.2008.07.002]Search in Google Scholar
[Revuelto, J., López-Moreno, J.I., Azorin-Molina, C., Vicente-Serrano, S.M., 2014. Topographic control on snowpack distribution in a small catchment in the central Pyrenees: intra- and inter-annual persistence. The Cryosphere, 8, 1989–2006.10.5194/tc-8-1989-2014]Search in Google Scholar
[Schrödter, H., 1985. Verdunstung - Anwendungsorientierte Meßverfahren und Bestimmungsmethoden. Springer Verlag, Berlin. (In German.)]Search in Google Scholar
[Sihvola, A., Tiuri, M., 1986. Snow fork for field determination of the density and wetness profiles of a snow pack. IEEE Transactions on Geoscience and Remote Sensing, GE24, 5, 717–721.10.1109/TGRS.1986.289619]Search in Google Scholar
[Tekeli, A.E., Şorman A.A., Şensoy, A., Şorman, A.Ü., 2003. Design, installation of a snowmelt lysimeter and analysis for an energy balance model studies in Turkey. In: 60th Eastern Snow Conference, Eastern Snow Conference, Sherbrooke, Quebec, Canada.]Search in Google Scholar
[Toikka, 2013. Snow Fork – manual. Ins. toimisto Toikka Oy, Espoo, Finland, 20 p.]Search in Google Scholar
[Vionnet, V., Brun, E., Morin, S., Boone, A., Faroux, S., Le Moigne, P., Martin, E., Willemet, J.-M., 2012. The detailed snowpack scheme Crocus and its implementation in SURFEX v7.2. Geosci. Model Dev., 5, 773–791. doi: 10.5194/gmd-5-773-2012.10.5194/gmd-5-773-2012]Search in Google Scholar
[Warscher, M., Strasser, U., Kraller, G., Marke, T., Franz, H., Kunstmann, H., 2013. Performance of complex snow cover descriptions in a distributed hydrological model system: a case study for the high Alpine terrain of the Berchtesgaden Alps. Alps. Water Resour. Res., 49, 5, 2619–2637.10.1002/wrcr.20219]Search in Google Scholar
[Weingartner, R., Barben, M., Spreafico, M., 2003. Floods in mountain areas – an overview based on examples from Switzerland. J. Hydrol., 282, 1–4, 10–24.10.1016/S0022-1694(03)00249-X]Search in Google Scholar
[Wever, N., Fierz, C., Mitterer, C., Hirashima, H., Lehning, M., 2014. Solving Richards equation for snow improves snow pack meltwater runoff estimations in detailed multi-layer snowpack model. Cryosphere, 8, 1, 257–274. http://dx.doi.org/10.5194/tc-8-257-2014]Search in Google Scholar
[Winstral, A., Elder, K., Davis, R.E., 2002. Spatial snow modeling of wind-redistributed snow using terrain-based parameters. Journal of Hydrometeorology, 3, 524–538.10.1175/1525-7541(2002)003<0524:SSMOWR>2.0.CO;2]Search in Google Scholar
[Winstral, A., Marks, D., Gurney, R., 2013. Simulating wind affected snow accumulations at catchment to basin scales. Advances in Water Resources, 55, 64–79.10.1016/j.advwatres.2012.08.011]Search in Google Scholar
[Zhang, F., Zhang, H., Hagen, S.C., Ye, M., Wang, D., Gui, D., Zeng, Ch., Tian, L., Liu, J., 2015. Snow cover and runoff modeling in a high mountain catchment with scarce data: effects of temperature and precipitation parameters. Hydrol. Process., 29, 52–65. doi: 10.1002/hyp.10125.10.1002/hyp.10125]Search in Google Scholar