Publications

Below you will find an overview of study sites in scientific literature that has used current or previous versions of the LISEM model.

Research Locations

For more details, please see the list of literature below. For each entry, the study site location (country) is stated, together with the processes that were part of research. This list is not complete, so be sure to check academic search tools for a more full list of works using LISEM.

Iran, Soil Erosion and Hydrology, Rahmati, M., Neyshabouri, M. R., Fakherifard, A., Oskouei, M. M., Ahmadi, A., & Sheikh, J. V. (2013). Rainfall-runoff prediction using LISEM model in Lighvan watershed, North West of Iran. Tech. J. Eng. Appl. Sci, 3(16), 1893-1901.

China, Soil Erosion, Chen, Y. B., Lin, C. W., Reijnders, J., & Stolte, J. (2007). Calibration and Validation of Limburg Soil Erosion Model (LISEM) for the Small Catchment in the Purple Hilly Masses of Sichuan Basin. 西南農業學報, 20(4), 669-675.

OpenLISEM Development, Baartman, J. E. M., Schoorl, J. M., Veldkamp, A., & Ritsema, C. J. (2010). Erosion in a landscape evolution context: LISEM and LAPSUS: variation in temporal and spatial scales. In Scaling and governance conference 2010: towards a new knowledge for scale sensitive governance of complex systems: conference program and book of abstracts.-Wageningen: Wageningen University and Research Centre (WUR), 2010.

OpenLISEM Development, Butzen, V., Seeger, K. M., Casper, M. C., & Ries, J. B. (2011). Parameterization of the process-based soil erosion model LISEM by means of experimental measurements.

Norway, Soil Erosion and Hydrology, Kværnø, S. H., & Stolte, J. (2012). Effects of soil physical data sources on discharge and soil loss simulated by the LISEM model. Catena, 97, 137-149.

South-Korea, Soil Erosion and Hydrology, Im, S. S., Kim, M., Kim, J. H., & Paik, K. (2012). Comparison of RUSLE and LISEM for the evaluation of spatial distribution of simulated sediment yield. Journal of the Korean Society of Hazard Mitigation, 12(5), 199-206.

France, Soil Erosion and Hydrology, Hessel, R., Gupta, M. K., Datta, P. S., & Gelderman, E. (2007). Application of the LISEM Soil Erosion Model to a Forested Catchment in the Indian Himalayas. International Journal of Ecology and Environmental Sciences, 33, 129-142.

India, Soil Erosion and Hydrology, Hessel, R., Gupta, M. K., Datta, P. S., & Gelderman, E. (2007). Application of the LISEM Soil Erosion Model to a Forested Catchment in the Indian Himalayas. International Journal of Ecology and Environmental Sciences, 33, 129-142.

Semi-Structured Mass Movement, van den Bout, B., van Asch, T. W., Hu, W., Tang, C., Mavrouli, O., Jetten, V. G., & van Westen, C. J. (2020). Towards a model for structured mass movements: the OpenLISEM Hazard model 2.0 a. Geoscientific Model Development Discussions, 1-31.

South-Korea, Flooding and Hydrology, Lee, J., van den Bout, B., & Lee, D. K. (2019, January). Analysis of flooding impact with multi-risk hazards scenario by using physically-based model. In Geophysical Research Abstracts (Vol. 21).

Phillipenes, Soil erosion and hydrology, Clutario, M. V. A., & David, C. P. (2014). Event-based soil erosion estimation in a tropical watershed. International Journal of Forest, Soil and Erosion (IJFSE), 4(2), 51-57.

Central Java, Flooding and Hydrology, Sudibyakto, H. A. (2014). Evaluation of Retention Basin Establishment to Reduce Flood Risk on Crops by Using Flood Modeling in Logung Sub-Catchment, Juwana Catchment, Central Java, Indonesia (Doctoral dissertation, [Yogyakarta]: Universitas Gadjah Mada).

Alps, Soil Erosion and Hydrology, AZUERO MERCADO, R. A., & DAHAL, A. (2019). Soil erosion modeling in alpine catchment basins.

Belgium, Soil Erosion and Hydrology, Ferket, B., Broek, M., Hoestenberghe, T. V., Degerickx, J., Sutter, R. D., Govers, G., … & Deproost, P. (2015). Erosion modelling towards, and sediment transport modelling in unnavigable watercourses in Flanders, Belgium. Proceedings of the International Association of Hydrological Sciences, 367, 349-356.

Spain, Landscape Evolution, Baartman, J. E. M., Temme, A. J. A. M., Veldkamp, A., Jetten, V., & Schoorl, J. M. (2013). Linking events to landscape evolution-comparing two models. In 8th International conference (AIG) on Geomorphology:“Geomorphology and sustainability”, Paris, France (p. 251).

Brazil, Hydrology and Flooding, de Barros, C. A. P., Govers, G., Minella, J. P. G., & Ramon, R. (2021). How water flow components affect sediment dynamics modeling in a Brazilian catchment. Journal of Hydrology, 126111.

Brazil, Hydrology, de Barros, C. A. P., Minella, J. P. G., Dalbianco, L., & Ramon, R. (2014). Description of hydrological and erosion processes determined by applying the LISEM model in a rural catchment in southern Brazil. Journal of soils and sediments, 14(7), 1298-1310.

Dominica, Italy, Flooding and numerics, Van Den Bout, B., & Jetten, V. G. (2020). Catchment-scale multi-process modeling with local time stepping. Environmental earth sciences, 79(8), 1-15.

Chile, Soil Erosion, Baumann Traine, V., Bonadonna, C., Cuomo, S., & Moscariello, M. (2019). Modelling of erosion processes associated with rainfall-triggered lahars following the 2011 Cordon Caulle eruption (Chile). Journal of Volcanology and Geothermal Research, (106727).

Granadas, Flooding and Hydrology, Pratomo, R. A. (2016, May). Sensitivity analysis of flash-flood modelling in Grenada, as a small island Caribbean states. In AIP Conference Proceedings (Vol. 1730, No. 1, p. 070002). AIP Publishing LLC.

Wenchuan, China, Co-seismic debris flows, Xiao, Y. (2020). Analyzing the predictive capacity of a physically-based debris flow model: a case study for debris flow in the post-2008 Wenchuan earthquake area (Master’s thesis, University of Twente).

Java, Flooding and Hydrology, Christanto, N., Sartohadi, J., Setiawan, A., Hadi, M. P., Jetten, V., & Shrestha, D. P. (2019). Investigating the Role of Rainfall Variability on the Hydrological Response of Small Tropical Upland Watershed. Jurnal Geografi: Media Informasi Pengembangan dan Profesi Kegeografian, 16(1).

Cape-Verde, Flooding and Hydrology, Sanchez‐Moreno, J. F., Jetten, V., Mannaerts, C. M., & de Pina Tavares, J. (2014). Selecting best mapping strategies for storm runoff modeling in a mountainous semi‐arid area. Earth surface processes and landforms, 39(8), 1030-1048.

Chile, Hydrology Erosion and Vulcanology, Baumann, V., Bonadonna, C., Cuomo, S., & Moscariello, M. (2020). Modelling of erosion processes associated with rainfall-triggered lahars following the 2011 Cordon Caulle eruption (Chile). Journal of Volcanology and Geothermal Research, 390, 106727.

Spain, Flooding and Erosion, Baartman, J. E., Temme, A. J., Veldkamp, T., Jetten, V. G., & Schoorl, J. M. (2013). Exploring the role of rainfall variability and extreme events in long-term landscape development. Catena, 109, 25-38.

Prado, South-Eastern Spain, Soil erosion and Hydrology, Baartman, J. E., Jetten, V. G., Ritsema, C. J., & de Vente, J. (2012). Exploring effects of rainfall intensity and duration on soil erosion at the catchment scale using openLISEM: Prado catchment, SE Spain. Hydrological processes, 26(7), 1034-1049.

Central Java, Flooding and Hydrology, Nurritasari, F. A., Sudibyakto, S., & Jetten, V. G. (2015). OpenLISEM Flash Flood Modelling Application in Logung Sub-Catchment, Central Java. Indonesian Journal of Geography, 47(2), 132-141.

Italy, Flooding and Hydrology, Liu, Y., Han, D., & Pregnolato, M. (2019, January). An optimized OpenLISEM model for flash floods in Emilia-Romagna, Italy. In Geophysical Research Abstracts (Vol. 21).

Kampala, Uganda, Flooding and Hydrology, Umer, Y., Jetten, V., & Ettema, J. (2019, January). Applying WRF-openLISEM model coupling system to simulate flash flood hazard in Kampala, Uganda. In Geophysical Research Abstracts (Vol. 21).

Sicily, Multi-Hazard, Bout, B., Lombardo, L., van Westen, C. J., & Jetten, V. G. (2018). Integration of two-phase solid fluid equations in a catchment model for flashfloods, debris flows and shallow slope failures. Environmental modelling & software, 105, 1-16.

Sicily, Slope Stability, Van den Bout, B., Lombardo, L., Chiyang, M., van Westen, C., & Jetten, V. (2021). Physically-based catchment-scale prediction of slope failure volume and geometry. Engineering Geology, 284, 105942.

Italy, Soil Erosion, Cuomo, S., Della Sala, M., & Novità, A. (2015). Physically based modelling of soil erosion induced by rainfall in small mountain basins. Geomorphology, 243, 106-115.

France, Pollution and Hydrology, Hong, Y., Bonhomme, C., Van den Bout, B., Jetten, V., & Chebbo, G. (2017). Integrating atmospheric deposition, soil erosion and sewer transport models to assess the transfer of traffic-related pollutants in urban areas. Environmental modelling & software, 96, 158-171.

Spain, Erosion and Hydrology, López‐Vicente, M., Quijano, L., Gaspar, L., Palazón, L., & Navas, A. (2015). Severe soil erosion during a 3‐day exceptional rainfall event: combining modelling and field data for a fallow cereal field. Hydrological processes, 29(10), 2358-2372.

The Netherlands, Erosion and Hydrology, De Roo, A. P. J., Wesseling, C. G., & Ritsema, C. J. (1996). LISEM: a single‐event physically based hydrological and soil erosion model for drainage basins. I: theory, input and output. Hydrological processes, 10(8), 1107-1117.

The Netherlands, Erosion and Hydrology, De Roo, A. P. J., Offermans, R. J. E., & Cremers, N. H. D. T. (1996). LISEM: A single‐event, physically based hydrological and soil erosion model for drainage basins. II: Sensitivity analysis, validation and application. Hydrological processes, 10(8), 1119-1126.

Netherlands and South Africa, Soil Erosion and Hydrology, De Roo, A. P. J., & Jetten, V. G. (1999). Calibrating and validating the LISEM model for two data sets from the Netherlands and South Africa. Catena, 37(3-4), 477-493.

OpenLISEM development, De Roo, A. P. J., Wesseling, C. G., Cremers, N. H. D. T., Offermans, R. J. E., Ritsema, C. J., & Van Oostindie, K. (1994). LISEM: a new physically-based hydrological and soil erosion model in a GIS-environment, theory and implementation. IAHS Publications-Series of Proceedings and Reports-Intern Assoc Hydrological Sciences, 224, 439-448.

OpenLISEM development, De Roo, A. P. J., Wesseling, C. G., Cremers, N. H. D. T., Offermans, R. J. E., Ritserma, C. J., Van Oostindie, K., … & HJ, S. (1996). LISEM: A physically-based hydrological and soil erosion model incorporated in a GIS. IAHS Publication, 235, 395-403.

OpenLISEM development, De Roo, A. P. J., & Offermans, R. J. E. (1995). LISEM: a physically-based hydrological and soil erosion model for basin-scale water and sediment management. International Association of Hydrological Sciences, Publication, (231), 399-407.

The Netherlands, Soil Erosion, Stolte, J., Ritsema, C. J., & De Roo, A. P. J. (1997). Effects of crust and cracks on simulated catchment discharge and soil loss. Journal of Hydrology, 195(1-4), 279-290.

Northern France, Soil Erosion, Jetten, V., de Roo, A., & Guérif, J. (1998). Sensitivity of the model LISEM to variables related to agriculture. In Modelling soil erosion by water (pp. 339-349). Springer, Berlin, Heidelberg.

OpenLISEM development, de Roo, A., Jetten, V., Wesseling, C., & Ritsema, C. (1998). LISEM: a physically-based hydrologic and soil erosion catchment model. In Modelling soil erosion by water (pp. 429-440). Springer, Berlin, Heidelberg.

OpenLISEM development, Jetten, V., de Roo, A., & Guérif, J. (1998). Sensitivity of the model LISEM to variables related to agriculture. In Modelling soil erosion by water (pp. 339-349). Springer, Berlin, Heidelberg.

China, Soil Erosion and Hydrology, Hessel, R., Jetten, V., Liu, B., Zhang, Y., & Stolte, J. (2003). Calibration of the LISEM model for a small Loess Plateau catchment. Catena, 54(1-2), 235-254.

The Netherlands, Soil Erosion and Hydrology, De Roo, A. P. J. (2000). Applying the LISEM model for investigating flood prevention and soil conservation scenarios in South-Limburg, The Netherlands. In Soil Erosion (pp. 33-41). Springer, Berlin, Heidelberg.

Laos, Soil Erosion and Hydrology, Chaplot, V., Giboire, G., Marchand, P., & Valentin, C. (2005). Dynamic modelling for linear erosion initiation and development under climate and land-use changes in northern Laos. Catena, 63(2-3), 318-328.

Northern Ethiopia, Grum, B., Woldearegay, K., Hessel, R., Baartman, J. E., Abdulkadir, M., Yazew, E., … & Geissen, V. (2017). Assessing the effect of water harvesting techniques on event-based hydrological responses and sediment yield at a catchment scale in northern Ethiopia using the Limburg Soil Erosion Model (LISEM). Catena, 159, 20-34.

Norway, Erosion and Hydrology, Starkloff, T., & Stolte, J. (2014). Applied comparison of the erosion risk models EROSION 3D and LISEM for a small catchment in Norway. Catena, 118, 154-167.

China, Erosion and Gullies, Stolte, J., Liu, B., Ritsema, C. J., Van Den Elsen, H. G. M., & Hessel, R. (2003). Modelling water flow and sediment processes in a small gully system on the Loess Plateau in China. Catena, 54(1-2), 117-130.

Tanzania and Kenya, Hessel, R., Van den Bosch, R., & Vigiak, O. (2006). Evaluation of the LISEM soil erosion model in two catchments in the East African Highlands. Earth Surface Processes and Landforms: The Journal of the British Geomorphological Research Group, 31(4), 469-486.

China, Hydrology, Hu, W., She, D., Shao, M. A., Chun, K. P., & Si, B. (2015). Effects of initial soil water content and saturated hydraulic conductivity variability on small watershed runoff simulation using LISEM. Hydrological Sciences Journal, 60(6), 1137-1154.

OpenLISEM Development, Jetten, V., Govers, G., & Hessel, R. (2003). Erosion models: quality of spatial predictions. Hydrological processes, 17(5), 887-900.

OpenLISEM Development, Takken, I., Govers, G., Jetten, V., Nachtergaele, J., Steegen, A., & Poesen, J. (2001). Effects of tillage on runoff and erosion patterns. Soil and Tillage Research, 61(1-2), 55-60.

OpenLISEM Development, Bout, B., & Jetten, V. G. (2018). The validity of flow approximations when simulating catchment-integrated flash floods. Journal of hydrology, 556, 674-688.