| Changes in snowpack accumulation and ablation in the intermountain west A Harpold, P Brooks, S Rajagopal, I Heidbuchel, A Jardine, C Stielstra Water Resources Research 48 (11), 2012 | 214 | 2012 |
| The master transit time distribution of variable flow systems I Heidbüchel, PA Troch, SW Lyon, M Weiler Water Resources Research 48 (6), 2012 | 172 | 2012 |
| Dealing with landscape heterogeneity in watershed hydrology: A review of recent progress toward new hydrological theory PA Troch, GA Carrillo, I Heidbüchel, S Rajagopal, M Switanek, ... Geography Compass 3 (1), 375-392, 2009 | 122 | 2009 |
| Consequences of mixing assumptions for time‐variable travel time distributions Y van Der Velde, I Heidbüchel, SW Lyon, L Nyberg, A Rodhe, K Bishop, ... Hydrological Processes 29 (16), 3460-3474, 2015 | 118 | 2015 |
| Separating physical and meteorological controls of variable transit times in zero‐order catchments I Heidbüchel, PA Troch, SW Lyon Water Resources Research 49 (11), 7644-7657, 2013 | 103 | 2013 |
| Use of cosmic-ray neutron sensors for soil moisture monitoring in forests I Heidbüchel, A Güntner, T Blume Hydrology and Earth System Sciences 20 (3), 1269-1288, 2016 | 87 | 2016 |
| Exploring the dynamics of transit times and subsurface mixing in a small agricultural catchment J Yang, I Heidbüchel, A Musolff, F Reinstorf, JH Fleckenstein Water Resources Research 54 (3), 2317-2335, 2018 | 83 | 2018 |
| What controls the stable isotope composition of precipitation in the Mekong Delta? A model-based statistical approach N Le Duy, I Heidbüchel, H Meyer, B Merz, H Apel Hydrology and Earth System Sciences 22 (2), 1239-1262, 2018 | 56 | 2018 |
| Groundwater dynamics in the Vietnamese Mekong Delta: Trends, memory effects, and response times N Le Duy, TVK Nguyen, DV Nguyen, AT Tran, HT Nguyen, I Heidbüchel, ... Journal of Hydrology: Regional Studies 33, 100746, 2021 | 42 | 2021 |
| On the shape of forward transit time distributions in low-order catchments I Heidbüchel, J Yang, A Musolff, P Troch, T Ferré, J Fleckenstein Hydrology and Earth System Sciences 24 (6), 2895-2920, 2020 | 16 | 2020 |
| Challenges in studying water fluxes within the soil-plant-atmosphere continuum: A tracer-based perspective on pathways to progress N Orlowski, M Rinderer, M Dubbert, N Ceperley, M Hrachowitz, A Gessler, ... Science of the Total Environment 881, 163510, 2023 | 12 | 2023 |
| Using nitrate as a tracer to constrain age selection preferences in catchments with strong seasonality J Yang, I Heidbüchel, A Musolff, Y Xie, C Lu, JH Fleckenstein Journal of Hydrology 603, 126889, 2021 | 11 | 2021 |
| Identification of groundwater mean transit times of precipitation and riverbank infiltration by two‐component lumped parameter models N Le Duy, NV Dung, I Heidbüchel, H Meyer, M Weiler, B Merz, H Apel Hydrological processes 33 (24), 3098-3118, 2019 | 5 | 2019 |
| Effect of topographic slope on the export of nitrate in humid catchments: a 3D model study J Yang, Q Wang, I Heidbüchel, C Lu, Y Xie, A Musolff, JH Fleckenstein Hydrology and Earth System Sciences 26 (19), 5051-5068, 2022 | 4 | 2022 |
| Recharge processes in ephemeral streams derived from a coupled stream flow routing/groundwater model—application to the Lower Kuiseb (Namibia) I Heidbüchel Doctoral dissertation, Thesis, Freiburg University, 2007 | 4 | 2007 |
| Flow paths and wetness conditions explain spatiotemporal variation of nitrogen retention for a temperate, humid catchment Q Wang, J Yang, I Heidbüchel, X Yu, C Lu Journal of Hydrology 625, 130024, 2023 | | 2023 |
| On the variability of hydrologic catchment response: Inherent and external controls I Heidbuechel The University of Arizona, 2013 | | 2013 |
Peter A. TrochThe University of Arizona在 hwr.arizona.edu 的电子邮件经过验证
