| Backwater rise due to large wood accumulations I Schalko, L Schmocker, V Weitbrecht, RM Boes Journal of Hydraulic Engineering 144 (9), 04018056, 2018 | 138 | 2018 |
| Laboratory flume experiments on the formation of spanwise large wood accumulations: Part II—Effect on local scour I Schalko, C Lageder, L Schmocker, V Weitbrecht, RM Boes Water Resources Research 55 (6), 4871-4885, 2019 | 73 | 2019 |
| Laboratory flume experiments on the formation of spanwise large wood accumulations: I. Effect on backwater rise I Schalko, C Lageder, L Schmocker, V Weitbrecht, RM Boes Water Resources Research 55 (6), 4854-4870, 2019 | 68 | 2019 |
| Laboratory study on wood accumulation probability at bridge piers I Schalko, L Schmocker, V Weitbrecht, RM Boes Journal of Hydraulic Research 58 (4), 566-581, 2020 | 50 | 2020 |
| Momentum and Energy Predict the Backwater Rise Generated by a Large Wood Jam E Follett, I Schalko, H Nepf Geophysical Research Letters, e2020GL089346, 2020 | 47 | 2020 |
| Flow and wake characteristics associated with large wood to inform river restoration I Schalko, E Wohl, HM Nepf Scientific Reports 11 (1), 8644, 2021 | 34 | 2021 |
| Modeling hazards related to large wood in rivers I Schalko ETH Zurich, 2018 | 31 | 2018 |
| Risk reduction measures of large wood accumulations at bridges I Schalko, L Schmocker, V Weitbrecht, RM Boes Environmental Fluid Mechanics 20, 485-502, 2020 | 28 | 2020 |
| Physical modelling of large wood (LW) processes relevant for river management: Perspectives from New Zealand and Switzerland H Friedrich, D Ravazzolo, V Ruiz‐Villanueva, I Schalko, G Spreitzer, ... Earth Surface Processes and Landforms 47 (1), 32-57, 2022 | 22 | 2022 |
| Wood retention at inclined racks: effects on flow and local bedload processes I Schalko Earth Surface Processes and Landforms, 2020 | 22 | 2020 |
| Logjams with a lower gap: Backwater rise and flow distribution beneath and through logjam predicted by two‐box momentum balance E Follett, I Schalko, H Nepf Geophysical Research Letters, e2021GL094279, 2021 | 21 | 2021 |
| Large wood accumulation probability at a single bridge pier I Schalko Proceedings of the 37th IAHR world congress, 1704-1713, 2017 | 16 | 2017 |
| Large wood research in Swiss watercourses V Ruiz-Villanueva, A Badoux, RM Boes, D Rickenmann, C Rickli, ... Proceedings of the International Conference on Fluvial Hydraulics, 2307-2314, 2016 | 10 | 2016 |
| Wood blockage and sediment transport at inclined bar screens I Schalko, V Weitbrecht Journal of Hydraulic Research 60 (1), 164-172, 2022 | 9 | 2022 |
| Backwater rise to do driftwood accumulation I Schalko, D Brändli, L Schmocker, V Weitbrecht, R Boes 13th Congress Interpraevent 2016: living with natural risks: 30 May to 2 …, 2016 | 9 | 2016 |
| Wood retention at inclined bar screens: Effect of wood characteristics on backwater rise and bedload transport I Schalko, V Ruiz-Villanueva, F Maager, V Weitbrecht Water 13 (16), 2231, 2021 | 8 | 2021 |
| Modeling the effect of organic fine material in a driftwood accumulation on backwater rise I Schalko, L Schmocker, V Weitbrecht, R Boes Proceedings of the International Conference on Fluvial Hydraulics (River …, 2016 | 8 | 2016 |
| Fuzzy-logic indicators for riverbed de-clogging suggest ecological benefits of large wood S Schwindt, B Negreiros, M Ponce, I Schalko, S Lassar, R Barros, S Haun Ecological Indicators 155, 111045, 2023 | 6 | 2023 |
| Impact of lateral gap on flow distribution, backwater rise, and turbulence generated by a logjam I Schalko, E Follett, H Nepf Water Resources Research 59 (10), e2023WR034689, 2023 | 6 | 2023 |
| Towards a non-intrusive method employing digital twin models for the assessment of complex large wood accumulations in fluvial environments G Spreitzer, I Schalko, RM Boes, V Weitbrecht Journal of Hydrology 614, 128505, 2022 | 5 | 2022 |
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