Caesar-Publications
From CSDMS
References Caesar
| Publication(s) | Year | Type | Cited |
|---|---|---|---|
| Coulthard, T.J.; Macklin, M.G.; Kirkby, M.J. 2002. A cellular model of Holocene upland river basin and alluvial fan evolution. Earth Surface Processes and Landforms, 27, 269–288. 10.1002/esp.318 (View/edit entry) | 2002 | Model overview | 351 |
| Van De Wiel, Marco J.; Coulthard, Tom J.; Macklin, Mark G.; Lewin, John; 2007. Embedding reach-scale fluvial dynamics within the CAESAR cellular automaton landscape evolution model. Geomorphology, 90, 283–301. 10.1016/j.geomorph.2006.10.024 (View/edit entry) | 2007 | Model overview | 164 |
| Hancock, Gr; Lowry, Jbc; Coulthard, Tj; Evans, Kg; Moliere, Dr; 2010. A catchment scale evaluation of the SIBERIA and CAESAR landscape evolution models. Earth Surface Processes and Landforms, 35, 863–875. 10.1002/esp.1863 (View/edit entry) | 2010 | Model application | 87 |
| Coulthard, Tom J.; Neal, Jeff C.; Bates, Paul D.; Ramirez, Jorge; de Almeida, Gustavo A. M.; Hancock, Greg R.; 2013. Integrating the LISFLOOD-FP 2D hydrodynamic model with the CAESAR model: implications for modelling landscape evolution. Earth Surface Processes and Landforms, 38, 1897–1906. 10.1002/esp.3478 (View/edit entry) | 2013 | Model overview | 235 |
| Coulthard, Tom. J.; Wiel, Marco. J. Van De; 2006. A cellular model of river meandering. Earth Surface Processes and Landforms, 31, 123–132. 10.1002/esp.1315 (View/edit entry) | 2006 | Model application | 123 |
| Coulthard, T.J.; Lewin, J.; Macklin, M.G.; 2005. Modelling differential catchment response to environmental change. Geomorphology, 69, 222–241. 10.1016/j.geomorph.2005.01.008 (View/edit entry) | 2005 | Model application | 155 |
| Coulthard, T.J.; Hicks, D.M.; Van De Wiel, M.J.; 2007. Cellular modelling of river catchments and reaches: Advantages, limitations and prospects. Geomorphology, 90, 192–207. 10.1016/j.geomorph.2006.10.030 (View/edit entry) | 2007 | Model application | 139 |
| Van De Wiel, Marco J.; Coulthard, Tom J.; 2010. Self-organized criticality in river basins: Challenging sedimentary records of environmental change. Geology, 38, 87–90. 10.1130/G30490.1 (View/edit entry) | 2010 | Model overview | 114 |
| Coulthard, Tom J.; Van De Wiel, Marco J.; 2007. Quantifying fluvial non linearity and finding self organized criticality? Insights from simulations of river basin evolution. Geomorphology, 91, 216–235. 10.1016/j.geomorph.2007.04.011 (View/edit entry) | 2007 | Model application | 95 |
| Welsh, K.E.; Dearing, J.A.; Chiverrell, R.C.; Coulthard, T.J.; 2009. Testing a cellular modelling approach to simulating late-Holocene sediment and water transfer from catchment to lake in the French Alps since 1826. The Holocene, 19, 785–798. 10.1177/0959683609105303 (View/edit entry) | 2009 | Model application | 45 |
| Coulthard, Tom J.; Hancock, Greg R.; Lowry, John B. C.; 2012. Modelling soil erosion with a downscaled landscape evolution model: MODELLING SOIL EROSION WITH A DOWNSCALED LEM. Earth Surface Processes and Landforms, 37, 1046–1055. 10.1002/esp.3226 (View/edit entry) | 2012 | Model application | 82 |
| Coulthard, T. J.; Ramirez, J.; Fowler, H. J.; Glenis, V.; 2012. Using the UKCP09 probabilistic scenarios to model the amplified impact of climate change on drainage basin sediment yield. Hydrology and Earth System Sciences, 16, 4401–4416. 10.5194/hess-16-4401-2012 (View/edit entry) | 2012 | Model application | 76 |
| Coulthard, Tom J.; Lewin, John; Macklin, Mark G.; 2007. 12 Non-stationarity of basin scale sediment delivery in response to climate change. In: (eds.)Developments in Earth Surface Processes.. 315–331. (View/edit entry) | 2007 | Model overview | 18 |
| Coulthard, T. J.; Van de Wiel, M. J.; 2013. Climate, tectonics or morphology: what signals can we see in drainage basin sediment yields?. Earth Surface Dynamics, 1, 13–27. 10.5194/esurf-1-13-2013 (View/edit entry) | 2013 | Model application | 75 |
| Hancock, G.R.; Coulthard, T.J.; Martinez, C.; Kalma, J.D.; 2011. An evaluation of landscape evolution models to simulate decadal and centennial scale soil erosion in grassland catchments. Journal of Hydrology, 398, 171–183. 10.1016/j.jhydrol.2010.12.002 (View/edit entry) | 2011 | Model application | 64 |
| Pender, Gareth; Faulkner, Hazel; Thorne, Colin; Wallerstein, Nick; Soar, Philip; Brookes, Andrew; Wishart, Duncan; Biedenharn, David; Gibson, Stanford; Little, Charles; Mooney, David; Watson, Chester C.; Green, Tony; Coulthard, Tom; 2010. Accounting for Sediment in Flood Risk Management. In: (eds.)Flood Risk Science and Management.. 87–113. (View/edit entry) | 2010 | Model application | 16 |
| Hancock, G. R.; Coulthard, T. J.; 2012. Channel movement and erosion response to rainfall variability in southeast Australia. Hydrological Processes, 26, 663–673. 10.1002/hyp.8166 (View/edit entry) | 2012 | Model application | 34 |
| Ziliani, L.; Surian, N.; Coulthard, T. J.; Tarantola, S.; 2013. Reduced-complexity modeling of braided rivers: Assessing model performance by sensitivity analysis, calibration, and validation: REDUCED-COMPLEXITY MODELING ASSESSMENT. Journal of Geophysical Research: Earth Surface, 118, 2243–2262. 10.1002/jgrf.20154 (View/edit entry) | 2013 | Model application | 69 |
| Shennan, I; Coulthard, T; Flather, R; Horton, B; Macklin, M; Rees, J; Wright, M; 2003. Integration of shelf evolution and river basin models to simulate Holocene sediment dynamics of the Humber Estuary during periods of sea-level change and variations in catchment sediment supply. The Science of The Total Environment, 314, 737–754. 10.1016/S0048-9697(03)00081-0 (View/edit entry) | 2003 | Model application | 38 |
| Hancock, G.R.; J.B.C., Lowry; Coulthard, T.J.; 2015. Catchment reconstruction — erosional stability at millennial time scales using landscape evolution models. Geomorphology, 231, 15–27. 10.1016/j.geomorph.2014.10.034 (View/edit entry) | 2015 | Model overview | 55 |
| Lang, Andreas; Dikau, Richard; Hennrich, Kirsten; Coulthard, Tom J.; Macklin, Mark G.; 2003. Long-term and large scale high resolution catchment modelling: Innovations and challenges arising from the NERC Land Ocean Interaction Study (LOIS). In: (eds.)Long Term Hillslope and Fluvial System Modelling.. 123–134. (View/edit entry) | 2003 | Model application | 4 |
| Skinner, Christopher J.; Coulthard, Thomas J.; Parsons, Daniel R.; Ramirez, Jorge A.; Mullen, Liam; Manson, Susan; 2015. Simulating tidal and storm surge hydraulics with a simple 2D inertia based model, in the Humber Estuary, U.K. Estuarine, Coastal and Shelf Science, 155, 126–136. 10.1016/j.ecss.2015.01.019 (View/edit entry) | 2015 | Model application | 53 |
| Barkwith, Andrew; Hurst, Martin D.; Jackson, Christopher R.; Wang, Lei; Ellis, Michael A.; Coulthard, Tom J.; 2015. Simulating the influences of groundwater on regional geomorphology using a distributed, dynamic, landscape evolution modelling platform. Environmental Modelling & Software, 74, 1–20. 10.1016/j.envsoft.2015.09.001 (View/edit entry) | 2015 | Model application | 15 |
| Ramirez, Jorge A.; Lichter, Michal; Coulthard, Tom J.; Skinner, Chris; 2016. Hyper-resolution mapping of regional storm surge and tide flooding: comparison of static and dynamic models. Natural Hazards, 82, 571–590. 10.1007/s11069-016-2198-z (View/edit entry) | 2016 | Model application | 97 |
| Church, Michael; Biron, Pascale M.; Roy, André G.; Coulthard, Thomas J.; Van De Wiel, Marco J.; 2012. Can We Link Cause and Effect in Landscape Evolution?. In: (eds.)Gravel-Bed Rivers.. 512–522. (View/edit entry) | 2012 | Related theory | 4 |
| Coulthard, Tom J.; Skinner, Christopher J.; 2016. The sensitivity of landscape evolution models to spatial and temporal rainfall resolution. Earth Surface Dynamics, 4, 757–771. 10.5194/esurf-4-757-2016 (View/edit entry) | 2016 | Model application | 41 |
| Coulthard, Tom J.; Van De Wiel, Marco J.; 2017. Modelling long term basin scale sediment connectivity, driven by spatial land use changes. Geomorphology, 277, 265–281. 10.1016/j.geomorph.2016.05.027 (View/edit entry) | 2017 | Model application | 77 |
| Veldkamp, A.; Baartman, J.E.M.; Coulthard, T.J.; Maddy, D.; Schoorl, J.M.; Storms, J.E.A.; Temme, A.J.A.M.; van Balen, R.; van De Wiel, M.J.; van Gorp, W.; Viveen, W.; Westaway, R.; Whittaker, A.C.; 2017. Two decades of numerical modelling to understand long term fluvial archives: Advances and future perspectives. Quaternary Science Reviews, 166, 177–187. 10.1016/j.quascirev.2016.10.002 (View/edit entry) | 2017 | Related theory | 19 |
| Howard, Andy J.; Knight, David; Coulthard, Tom; Hudson-Edwards, Karen; Kossoff, David; Malone, Steve; 2016. Assessing riverine threats to heritage assets posed by future climate change through a geomorphological approach and predictive modelling in the Derwent Valley Mills WHS, UK. Journal of Cultural Heritage, 19, 387–394. 10.1016/j.culher.2015.11.007 (View/edit entry) | 2016 | Model application | 39 |
| Liu, Baoli; Coulthard, Tom J.; 2017. Modelling the interaction of aeolian and fluvial processes with a combined cellular model of sand dunes and river systems. Computers & Geosciences, 106, 1–9. 10.1016/j.cageo.2017.05.003 (View/edit entry) | 2017 | Model overview | 35 |
| Zellou, Bouchra; Rahali, Hassane; 2017. Assessment of reduced-complexity landscape evolution model suitability to adequately simulate flood events in complex flow conditions. Natural Hazards, 86, 1–29. 10.1007/s11069-016-2671-8 (View/edit entry) | 2017 | Model application | 33 |
| Hancock, G.R.; Verdon-Kidd, D.; Lowry, J.B.C.; 2017. Soil erosion predictions from a landscape evolution model – An assessment of a post-mining landform using spatial climate change analogues. Science of The Total Environment, 601, 109–121. 10.1016/j.scitotenv.2017.04.038 (View/edit entry) | 2017 | Model application | 29 |
| Hancock, G.R.; Saynor, M.; Lowry, J.B.C.; Erskine, W.D.; 2020. How to account for particle size effects in a landscape evolution model when there is a wide range of particle sizes. Environmental Modelling & Software, 124, 104582. 10.1016/j.envsoft.2019.104582 (View/edit entry) | 2020 | Model application | 8 |
| Hancock, G.R.; Verdon-Kidd, D.; Lowry, J.B.C.; 2017. Sediment output from a post-mining catchment – Centennial impacts using stochastically generated rainfall. Journal of Hydrology, 544, 180–194. 10.1016/j.jhydrol.2016.11.027 (View/edit entry) | 2017 | Model application | 15 |
| Skinner, Christopher J.; Coulthard, Tom J.; Schwanghart, Wolfgang; Van De Wiel, Marco J.; Hancock, Greg; 2018. Global sensitivity analysis of parameter uncertainty in landscape evolution models. Geoscientific Model Development, 11, 4873–4888. 10.5194/gmd-11-4873-2018 (View/edit entry) | 2018 | Model application | 41 |
| Lowry, John; Coulthard, Tom; Hancock, Gregory; Jones, David; 2011. Assessing soil erosion on a rehabilitated landform using the CAESAR landscape evolution model ©. . Volume . (View/edit entry) | 2011 | Model application | 8 |
| Lowry, J.B.C.; Narayan, M.; Hancock, G.R.; Evans, K.G.; 2019. Understanding post-mining landforms: Utilising pre-mine geomorphology to improve rehabilitation outcomes. Geomorphology, 328, 93–107. 10.1016/j.geomorph.2018.11.027 (View/edit entry) | 2019 | Model application | 21 |
| Xie, Jun; Wang, Ming; Liu, Kai; Coulthard, Tom J.; 2018. Modeling sediment movement and channel response to rainfall variability after a major earthquake. Geomorphology, 320, 18–32. 10.1016/j.geomorph.2018.07.022 (View/edit entry) | 2018 | Model application | 16 |
| Slingerland, Neeltje; Beier, Nicholas; Wilson, Gordon; 2019. Stress testing geomorphic and traditional tailings dam designs for closure using a landscape evolution model. . Volume . (View/edit entry) | 2019 | Model application | 3 |
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| Nr. of publications: | 67 |
| Total citations: | 2798 |
| h-index: | 29 |
| m-quotient: | 1.21 |
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