about
A review on regional convection-permitting climate modeling: Demonstrations, prospects, and challenges.Hyper-resolution global hydrological modelling: what is next?A serendipitous, long-term infiltration experiment: water and tritium circulation beneath the CAMBRIC trench at the Nevada Test Site.Modeling Soil Processes: Review, Key Challenges, and New PerspectivesSoil hydrology: Recent methodological advances, challenges, and perspectivesImpacts of grid resolution on surface energy fluxes simulated with an integrated surface-groundwater flow modelHuman Water Use Impacts on the Strength of the Continental Sink for Atmospheric WaterReply to comment by Keith J. Beven and Hannah L. Cloke on “Hyperresolution global land surface modeling: Meeting a grand challenge for monitoring Earth's terrestrial water”Introduction of an Experimental Terrestrial Forecasting/Monitoring System at Regional to Continental Scales Based on the Terrestrial System Modeling Platform (v1.1.0)Connection Between Root Zone Soil Moisture and Surface Energy Flux Partitioning Using Modeling, Observations, and Data Assimilation for a Temperate Grassland Site in GermanyThe integrated hydrologic model intercomparison project, IH-MIP2: A second set of benchmark results to diagnose integrated hydrology and feedbacksNovel basin modelling concept for simulating deformation from mechanical compaction using level setsStudying the influence of groundwater representations on land surface-atmosphere feedbacks during the European heat wave in 2003Inter-comparison of three distributed hydrological models with respect to seasonal variability of soil moisture patterns at a small forested catchmentScale dependent parameterization of soil hydraulic conductivity in 3D simulation of hydrological processes in a forested headwater catchmentThe imprint of climate and geology on the residence times of groundwaterMonitoring and Modeling the Terrestrial System from Pores to Catchments: The Transregional Collaborative Research Center on Patterns in the Soil–Vegetation–Atmosphere SystemSpatio-temporal validation of long-term 3D hydrological simulations of a forested catchment using empirical orthogonal functions and wavelet coherence analysisA Scale-Consistent Terrestrial Systems Modeling Platform Based on COSMO, CLM, and ParFlowImplementation and scaling of the fully coupled Terrestrial Systems Modeling Platform (TerrSysMP v1.0) in a massively parallel supercomputing environment – a case study on JUQUEEN (IBM Blue Gene/Q)Introduction of a web service for cloud computing with the integrated hydrologic simulation platform ParFlowBoundedness of Turbulent Temperature Probability Distributions, and their Relation to the Vertical Profile in the Convective Boundary LayerChanging structure of European precipitation: Longer wet periods leading to more abundant rainfallsPatterns in Soil–Vegetation–Atmosphere Systems: Monitoring, Modeling, and Data AssimilationInfluence of soil heterogeneity on evapotranspiration under shallow water table conditions: transient, stochastic simulationsComment on “Sensitivity Analysis and Determination of Streambed Leakance and Aquifer Hydraulic Properties” by Xunhong Chen and Xi Chen, Journal of Hydrology, 2003, vol. 284, 270–284Introduction of an Experimental Terrestrial Forecasting/Monitoring System at Regional to Continental Scales Based on the Terrestrial Systems Modeling Platform (v1.1.0)Introduction of an Experimental Terrestrial Forecasting/Monitoring System at Regional to Continental Scales Based on the Terrestrial System Modeling Platform (v1.1.0)Pan-European groundwater to atmosphere terrestrial systems climatology from a physically consistent simulationSoil structure is an important omission in Earth System Models
P50
Q30378117-C8CFB709-9764-4A88-9901-DF8C9EC9C49BQ46570336-B5484622-9EA7-40A6-AA18-59F4115753A0Q47271383-8D6E8E89-E90B-4BB2-92E5-9AE853B3B452Q57238825-4723F6F9-ABFB-4236-A1CB-21B6A6BE7090Q57238847-93A02A47-CD55-40D6-8269-4DD20F419224Q57864956-D4BF96C0-C7B4-4129-A83F-F6142461E71DQ57876386-2A10BE45-657F-493D-B0A8-270A0E121B33Q58073906-518BAFF9-1CD6-4EF2-97C9-8D0E21C08FFCQ58102287-71796F9A-6025-4F57-AFF5-175998BE6B8BQ58102292-799BC2E7-BA8B-4713-850E-6892C4BDA978Q58102299-8CD3750D-DA3C-44B8-98FD-63079327E42DQ58102309-A9F78D4C-F172-42DB-BE77-03872DA5BA46Q58102313-2876B6CA-18D6-4DD5-9BF1-36B2CDE02B64Q58102328-455571AE-210D-4F24-BA80-3E62729E24EBQ58102333-C429D250-9121-48D9-A713-A4C03215700EQ58102339-9258F196-2E5F-4D81-AFA4-1B4CEDDE4E7AQ58102354-C07F1438-C734-4EBA-B9A9-6D0DF016401EQ58102358-9B3B0463-7FF8-4B24-9842-907F578FCC66Q58102368-0BDBBE96-09DD-4467-900B-B54A1B0102F4Q58102376-2B933D88-6C30-4F76-91FF-03973AF35610Q58102391-A9EAAC82-14D7-4842-A015-EB753040353DQ58102397-33C02C31-5FE5-4A3C-A67A-FE73CB111B4BQ58102400-A9A41430-6F21-4DB3-A164-3FD93AC815EAQ58102405-5B43EF9B-0832-44EB-B652-0A2CF1209AEDQ58102420-3EE0D812-51FA-4F49-B358-6B54ABA83862Q58102463-2AD4C4C0-4690-46D1-A6B7-78334CD51A94Q59316368-9D2989C3-1262-43EC-9477-D6EA7E434F44Q61734394-F042AC78-3DE1-4AA5-BA7A-9B22855DA6E0Q92024480-1D56B196-2A79-4BDC-B4D2-39E3B05826EEQ92978141-4CF8F02A-1E6F-4808-B282-54ADBCBCD9FB
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Stefan Kollet
@ast
Stefan Kollet
@en
Stefan Kollet
@es
Stefan Kollet
@nl
Stefan Kollet
@sl
type
label
Stefan Kollet
@ast
Stefan Kollet
@en
Stefan Kollet
@es
Stefan Kollet
@nl
Stefan Kollet
@sl
prefLabel
Stefan Kollet
@ast
Stefan Kollet
@en
Stefan Kollet
@es
Stefan Kollet
@nl
Stefan Kollet
@sl
P106
P1153
6506544018
P21
P31
P496
0000-0003-0095-1554