UEB-Publications
From CSDMS
References UEB
Publication(s) | Year | Type | Cited |
---|---|---|---|
Mahat, V.; 2011. Effect of Vegetation on the Accumulation and Melting of Snow at the TW Daniels Experimental Forest.. , , http://digitalcommons.usu.edu/etd/1078/. (View/edit entry) | 2011 | Model overview | 3 |
Mahat, Vinod; Tarboton, David G.; 2012. Correction to “Canopy radiation transmission for an energy balance snowmelt model”: CORRECTION. Water Resources Research, 48, . 10.1029/2012WR011964 (View/edit entry) | 2012 | Model application | 7 |
Mahat, Vinod; Tarboton, David G.; 2012. Canopy radiation transmission for an energy balance snowmelt model: CANOPY RADIATION FOR SNOWMELT. Water Resources Research, 48, . 10.1029/2011WR010438 (View/edit entry) | 2012 | Model application | 83 |
You, J.; 2004. Snow Hydrology: The Parameterization of Subgrid Processes within a Physically Based Snow Energy and Mass Balance Model. , , http://www.neng.usu.edu/cee/faculty/dtarb/yjs_dissertation.pdf. (View/edit entry) | 2004 | Model overview | 0 |
Luce, C. H.; 2000. Scale Influences on the Representation of Snowpack Processes. , , http://www.neng.usu.edu/cee/faculty/dtarb/lucedef.html. (View/edit entry) | 2000 | Model overview | 0 |
Mahat, Vinod; Tarboton, David G.; Molotch, Noah P.; 2013. Testing above- and below-canopy representations of turbulent fluxes in an energy balance snowmelt model: MODELING CANOPY TURBULENT TRANSFER PROCESSES OVER SNOW. Water Resources Research, 49, 1107–1122. 10.1002/wrcr.20073 (View/edit entry) | 2013 | Model overview | 81 |
Luce, C. H.; Tarboton, D. G.; 2010. Evaluation of alternative formulae for calculation of surface temperature in snowmelt models using frequency analysis of temperature observations. Hydrology and Earth System Sciences, 14, 535–543. 10.5194/hess-14-535-2010 (View/edit entry) | 2010 | Model overview | 44 |
Luce, Charles H.; Tarboton, David G.; 2004. The application of depletion curves for parameterization of subgrid variability of snow. Hydrological Processes, 18, 1409–1422. 10.1002/hyp.1420 (View/edit entry) | 2004 | Model overview | 95 |
Tarboton, D.G.; Blöschl, G.; Cooley, K.; Kirnbauer, R.; Luce, C.; 2000. Spatial Snow Cover Processes at Kühtai and Reynolds Creek. In: Grayson, R.; Blöschl, G.; (eds.)Spatial Patterns in Catchment Hydrology: Observations and Modelling.. 158-186. (View/edit entry) | 2000 | Model application | 102 |
Luce, Charles H.; Tarboton, David G.; Cooley, Keith R.; 1999. Sub-grid parameterization of snow distribution for an energy and mass balance snow cover model. Hydrological Processes, 13, 1921–1933. 10.1002/(SICI)1099-1085(199909)13:12/133.0.CO;2-S (View/edit entry) | 1999 | Model overview | 162 |
Luce, Charles H.; Tarboton, David G.; Cooley, Keith R.; 1998. The influence of the spatial distribution of snow on basin-averaged snowmelt. Hydrological Processes, 12, 1671–1683. 10.1002/(SICI)1099-1085(199808/09)12:10/113.0.CO;2-N (View/edit entry) | 1998 | Model overview | 219 |
Tarboton, D.G.; Chowdhury, T.G.; Jackson, T.H.; 1993. A Spatially Distributed Energy Balance Snowmelt Model. IAHS Publ. no. 228. Volume . (View/edit entry) | 1993 |
Model overview | 165 |
Lapo, Karl E.; Hinkelman, Laura M.; Raleigh, Mark S.; Lundquist, Jessica D.; 2015. Impact of errors in the downwelling irradiances on simulations of snow water equivalent, snow surface temperature, and the snow energy balance. Water Resources Research, 51, 1649–1670. 10.1002/2014WR016259 (View/edit entry) | 2015 |
Model application | 90 |
Raleigh, Mark S.; Livneh, Ben; Lapo, Karl; Lundquist, Jessica D.; 2016. How Does Availability of Meteorological Forcing Data Impact Physically Based Snowpack Simulations?*. Journal of Hydrometeorology, 17, 99–120. 10.1175/JHM-D-14-0235.1 (View/edit entry) | 2016 | Model application | 53 |
Brown, M.E.; Racoviteanu, A.E.; Tarboton, D.G.; Gupta, A. Sen; Nigro, J.; Policelli, F.; Habib, S.; Tokay, M.; Shrestha, M.S.; Bajracharya, S.; Hummel, P.; Gray, M.; Duda, P.; Zaitchik, B.; Mahat, V.; Artan, G.; Tokar, S.; 2014. An integrated modeling system for estimating glacier and snow melt driven streamflow from remote sensing and earth system data products in the Himalayas. Journal of Hydrology, 519, 1859–1869. 10.1016/j.jhydrol.2014.09.050 (View/edit entry) | 2014 |
Model application | 53 |
Wu, Xuejiao; Wang, Ninglian; Shen, Yongping; He, Jianqiao; Zhang, Wei; 2014. In-situ observations and modeling of spring snowmelt processes in an Altay Mountains river basin. Journal of Applied Remote Sensing, 8, 084697. 10.1117/1.JRS.8.084697 (View/edit entry) | 2014 | Model application | 4 |
Schulz, O.; de Jong, C.; 2004. Snowmelt and sublimation: field experiments and modelling in the High Atlas Mountains of Morocco. Hydrology and Earth System Sciences, 8, 1076–1089. 10.5194/hess-8-1076-2004 (View/edit entry) | 2004 | Model application | 102 |
Mahat, Vinod; Tarboton, David G.; 2014. Representation of canopy snow interception, unloading and melt in a parsimonious snowmelt model. Hydrological Processes, 28, 6320–6336. 10.1002/hyp.10116 (View/edit entry) | 2014 | Model application | 50 |
Sen Gupta, Avirup; Tarboton, David G.; 2016. A tool for downscaling weather data from large-grid reanalysis products to finer spatial scales for distributed hydrological applications. Environmental Modelling & Software, 84, 50–69. 10.1016/j.envsoft.2016.06.014 (View/edit entry) | 2016 | Model application | 34 |
Sultana, R.; Hsu, K.-L.; Li, J.; Sorooshian, S.; 2014. Evaluating the Utah Energy Balance (UEB) snow model in the Noah land-surface model. Hydrology and Earth System Sciences, 18, 3553–3570. 10.5194/hess-18-3553-2014 (View/edit entry) | 2014 | Model application | 16 |
Watson, Fred G.R.; Newman, Wendi B.; Coughlan, Joseph C.; Garrott, Robert A.; 2006. Testing a distributed snowpack simulation model against spatial observations. Journal of Hydrology, 328, 453–466. 10.1016/j.jhydrol.2005.12.012 (View/edit entry) | 2006 | Model application | 42 |
Sen Gupta, A.; Tarboton, D.G.; Hummel, P.; Brown, M.E.; Habib, S.; 2015. Integration of an energy balance snowmelt model into an open source modeling framework. Environmental Modelling & Software, 68, 205–218. 10.1016/j.envsoft.2015.02.017 (View/edit entry) | 2015 | Model application | 12 |
You, J.; Tarboton, D. G.; Luce, C. H.; 2014. Modeling the snow surface temperature with a one-layer energy balance snowmelt model. Hydrology and Earth System Sciences, 18, 5061–5076. 10.5194/hess-18-5061-2014 (View/edit entry) | 2014 | Model application | 19 |
Hellström, Robert Å; 2000. Forest cover algorithms for estimating meteorological forcing in a numerical snow model. Hydrological Processes, 14, 3239–3256. <3239::AID-HYP201>3.0.CO;2-O 10.1002/1099-1085(20001230)14:18<3239::AID-HYP201>3.0.CO;2-O (View/edit entry) | 2000 | Model application | 40 |
Gichamo, Tseganeh Z.; Tarboton, David G.; 2020. UEB parallel: Distributed snow accumulation and melt modeling using parallel computing. Environmental Modelling & Software, 125, 104614. 10.1016/j.envsoft.2019.104614 (View/edit entry) | 2020 | Model application | 4 |
Gardiner, Michael J.; Ellis-Evans, J. Cynan; Anderson, Malcolm G.; Tranter, Martyn; 1998. Snowmelt modelling on signy island, South Orkney Islands. Annals of Glaciology, 26, 161–166. 10.1017/S0260305500014749 (View/edit entry) | 1998 | Model application | 9 |
Liu, Yan; Zhang, Pu; Nie, Lei; Xu, Jianhui; Lu, Xinyu; Li, Shuai; 2019. Exploration of the Snow Ablation Process in the Semiarid Region in China by Combining Site-Based Measurements and the Utah Energy Balance Model—A Case Study of the Manas River Basin. Water, 11, 1058. 10.3390/w11051058 (View/edit entry) | 2019 | Model application | 7 |
Yu, Lianyu; Zeng, Yijian; Su, Zhongbo; 2021. STEMMUS-UEB v1.0.0: Integrated Modelling of Snowpack and Soil Mass and Energy Transfer with Three Levels of Soil Physical Process Complexities. . (View/edit entry) | 2021 | Model application | 1 |
Yu, Lianyu; Zeng, Yijian; Su, Zhongbo; 2021. STEMMUS-UEB v1.0.0: Integrated Modelling of Snowpack and Soil Mass and Energy Transfer with Three Levels of Soil Physical Process Complexities. . (View/edit entry) | 2021 |
Model application | 1 |
Gichamo, Tseganeh Z.; Tarboton, David G.; 2019. Ensemble Streamflow Forecasting Using an Energy Balance Snowmelt Model Coupled to a Distributed Hydrologic Model with Assimilation of Snow and Streamflow Observations. Water Resources Research, 55, 10813–10838. 10.1029/2019WR025472 (View/edit entry) | 2019 |
Model application | 10 |
Gichamo, Tseganeh Zekiewos; 2019. Advancing Streamflow Forecasts Through the Application of a Physically Based Energy Balance Snowmelt Model With Data Assimilation and Cyberinfrastructure Resources. , , https://digitalcommons.usu.edu/etd/7463. 10.26076/2QVV-5Z87 (View/edit entry) | 2019 |
Model application | 2 |
Gardiner, Michael J.; Ellis-Evans, J. Cynan; Anderson, Malcolm G.; Tranter, Martyn; 1998. Snowmelt modelling on signy island, South Orkney Islands. Annals of Glaciology, 26, 161–166. 10.3189/1998AoG26-1-161-166 (View/edit entry) | 1998 |
Model application | 9 |
Homan, Joel W.; Luce, Charles H.; McNamara, James P.; Glenn, Nancy F.; 2011. Improvement of distributed snowmelt energy balance modeling with MODIS-based NDSI-derived fractional snow-covered area data. Hydrological Processes, 25, 650–660. 10.1002/hyp.7857 (View/edit entry) | 2011 |
Model application | 55 |
Liu, Yan; Xu, Jianhui; Lu, Xinyu; Nie, Lei; 2020. Assessment of glacier‐ and snowmelt‐driven streamflow in the arid middle Tianshan Mountains of China. Hydrological Processes, 34, 2750–2762. 10.1002/hyp.13760 (View/edit entry) | 2020 |
Model application | 11 |
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Citations
Nr. of publications: | 34 |
Total citations: | 1585 |
h-index: | 18 |
m-quotient: | 0.58 |
Publications per year