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This page provides a simple browsing interface for finding entities described by a property and a named value. Other available search interfaces include the page property search, and the ask query builder.

List of results

• Model:ParFlow  + (Depends upon application.)
• Model:GOLEM  + (Designed for time scales over which topography changes appreciably, which might be years for badlands, up to thousands or millions of years for other landscapes.)
• Model:AquaTellUs  + (Developed as a stratigraphic model, approach is event-based. Intended time scale ranges from several decades to Holocene (10-10.000yrs).)
• Model:TopoFlow  + (Each process can have its own timestep. Typical timesteps are: *Channel flow (seconds) *Infiltration (seconds to minutes) *Snowmelt (hours to days) *Subsurface flow (hours to days), etc. Model can be run for a full year or longer, if necessary.)
• Model:CASCADE  + (Evolution of Myrs, due to the model parameterization used (no human-scale proceses))
• Model:Bing  + (For stability, time step is typically fractions of a second)
• Model:TUGS  + (For typical application in a natural river as a prediction tool, the recommended resolution is annual, although it can be as high as hours for simulation of a specific known event.)
• Model:GPM  + (From seconds to about 100,000 years.)
• Model:GENESIS  + (GENESIS is a long-term shoreline evolution model and is best applied to estimate shoreline change over time periods of 1 year to 10's of years.)
• Model:MarshMorpho2D  + (Generally runs with very large time steps (1 year) Cannot resolve intra-tidal processes (i.e., ebb-flood variability))
• Model:NearCoM  + (Hours to months.)
• Model:ROMS  + (Hours, days, seasons. It also can be used for climate research (decades).)
• Model:ChesROMS  + (Hours, days, seasons. It also can be used for climate research (decades).)
• Model:CBOFS2  + (Hours, days, seasons. It also can be used for climate research (decades).)
• Model:UMCESroms  + (Hours, days, seasons. It also can be used for climate research (decades).)
• Model:CAM-CARMA  + (I am running the model with dynamical time steps of 1800 seconds, but it only computes the radiative transfer every 200 timesteps.)
• Model:Cyclopath  + (Internal time step years to decades Model chron resolution 1000 years Total run time 1-10 My)
• Model:AnugaSed  + (Internal timestep is determined by ANUGA for numerical stability (in seconds). Output timestep is set by the user. Simulations are realistically limited to a few model hours.)
• Model:Morphodynamic gravel bed  + (It is applied for 90 years. The time step is ~0.7 days.)
• Model:GullyErosionProfiler1D  + (It is typically run for times no less than 25 years and no greater than 700 years.)
• Model:WBMsed  + (It simulate at daily time-steps. Maximum available datasets time-span is between 1901-present.)
• Model:River Network Bed-Material Sediment  + (Limited by computational resources.)
• Model:Nitrate Network Model  + (Limited by computational resources.)
• Model:LISFLOOD  + (Long-term water balance can be simulated (using a daily time step), as can individual flood events (using hourly time intervals, or even smaller). The output of a “water balance run” can be used to provide the initial conditions of a “flood run”.)
• Model:GRLP  + (Longer than the intermittency between channel-forming events)

• Model:DeltaClassification  + (Mapview at a given time)

• Model:BITM  + (Millennial scale)
• Model:HydroTrend  + (Minimal runtime: 1yr; up to > 10kyrs Daily discharge is the smallest output timestep)
• Model:RiverMUSE  + (Model constructed for daily time steps, but can be altered with little effort.)
• Model:Lake-Permafrost with Subsidence  + (Model needs daily (or smaller) timesteps.)
• Model:CoastMorpho2D  + (Morphological time steps can be on the order of years Time steps shorter than one tidal period are not realistic)
• Model:GEOtop  + (Most forcings are required at hourly scale. Integration time step is what required by numerical algorithms to converge (depends actually on processes))
• Model:DeltaSIM  + (Mostly tested for Holocene applications (>10,000yrs), potentially longer time scales.)
• Model:Non Local Means Filtering  + (N/A)
• Model:BOM  + (No assimilation means it works best for simulations shorter than ~6months unless boundary conditions are carefully tuned to avoid model drift.)
• Model:DrEICH algorithm  + (No time resolution constraints as this software performs topographic analysis.)
• Model:SurfaceRoughness  + (No time resolution constraints as this software performs topographic analysis.)
• Model:Hilltop flow routing  + (No time resolution constraints as this software performs topographic analysis.)
• Model:HexWatershed  + (None)
• Model:MARSSIM V4  + (None except elapsed time and memory limits.)
• Model:AR2-sinuosity  + (Not applicable - the model generates static channel planforms.)
• Model:Mrip  + (One second has been the time resolution. I haven't played with this.)
• Model:GNE  + (Operates at annual scale; monthly-seasonal time steps are being explored.)
• Model:NEXRAD-extract  + (Radar sweeps every approx. 15 minutes)
• Model:SBEACH  + (SBEACH is a short-term storm processes model and is intended for the estimation of beach profile response to storm events. Typical simulation durations are limited to hours to days (1 week maximum).)
• Model:PyDeltaRCM  + (Sediment and water discharge come from some physical parameters and the number of parcels chosen for each timestep. Set the number of parcels for both water and sediment to 1000s for improved resolution and speed.)
• Model:PHREEQC  + (See 'Description of Input and Examples for PHREEQC Version 3 - A computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations'.)
• Model:WRF-Hydro  + (See WRF-Hydro Technical Description https://ral.ucar.edu/projects/wrf_hydro/technical-description-user-guide)
• Model:CellularFanDelta  + (See above.)
• Model:SPHYSICS  + (See manual)
• Model:FwDET  + (See: Version 2.0: Cohen et al. (2019), The … See:</br>Version 2.0: Cohen et al. (2019), The Floodwater Depth Estimation Tool (FwDET v2.0) for Improved Remote Sensing Analysis of Coastal Flooding. Natural Hazards and Earth System Sciences (NHESS)</br> </br>Version 1.0: Cohen, S., G. R. Brakenridge, A. Kettner, B. Bates, J. Nelson, R. McDonald, Y. Huang, D. Munasinghe, and J. Zhang (2017), Estimating Floodwater Depths from Flood Inundation Maps and Topography. Journal of the American Water Resources Association (JAWRA):1–12. Water Resources Association (JAWRA):1–12.)