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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:BRaKE  + (Domain size/length/spacing, time to run, t … Domain size/length/spacing, time to run, timestep, hillslope response timescale, baselevel lowering rate, bed erodibility, block erodibility, bed critical shear stress, block critical shear stress, block delivery coefficient, initial block size, roughness length scale, channel width, mean discharge, discharge variability, and data recording time interval.ability, and data recording time interval.)
• Model:HydroTrend  + (Drainage basin properties (river networks, hypsometry, relief, reservoirs). biophysical parameters (temperature, precipitation, evapo-transpiration, and glacier characteristics).)
• Model:SFINCS  + (Elevation file and a mask file designating boundary cells, active cells, and inactive cells)
• Model:GEOMBEST  + (Excel files. See User's Guide and Moore et al., 2010)
• Model:1DBreachingTurbidityCurrent  + (Excel sheet. User can change initial geome … Excel sheet. User can change initial geometry data (slope at top of breach, initial height of breach face, initial bed slope in quasi-horizontal region, initial location of breach face, initial length of quasi-horizontal region); sediment grain size distribution; sediment properties (bed porosity, breach porosity, bed friction coefficient, wall friction coefficient, submerged specific gravity); and time evolution (time step, number of time steps, initial number of nodes in horizontal, print interval, calculation time).zontal, print interval, calculation time).)
• Model:SVELA  + (Flow velocity, friction slope, hydraulic radius, and bed roughness)
• Model:WRF-Hydro  + (For a complete explanation of input parame … For a complete explanation of input parameters please see the WRF-Hydro Technical Description https://ral.ucar.edu/projects/wrf_hydro/technical-description-user-guide</br>WRF-Hydro requires a number of input files describing the model domain, parameters, initial</br>conditions, hydrologic routing, and when run in a standalone configuration, meteorological forcing files.nfiguration, meteorological forcing files.)
• Model:DLBRM  + (For every cell in the watershed grid, dail … For every cell in the watershed grid, daily precipitation and air temperature, solar isolation, elevation, slope, flow direction, land use, depths (cm) of USZ (Upper Soil Zone) and LSZ (Lower Soil Zone), available water capacity (%) of USZ and LSZ, soil texture, permeability (cm/h) of USZ and LSZ, Manning's coefficient values, and daily flows (Changsheng He and Thomas E. Croley II, 2007).ngsheng He and Thomas E. Croley II, 2007).)
• Model:TopoFlow-Diversions  + (For sources and sinks, the following infor … For sources and sinks, the following information must be provided, each on its own line:</br> ID (source pixel ID as long integer; calendar index)</br> nd (number of durations and flow rates)</br> durations (vector of durations in minutes)</br> flow rates (vector of discharges in m^3/sec)</br></br>For canals, the following information must be provided, again with each entry on a separate line in the text file:</br> ID1 (start pixel ID as long integer; calendar index)</br> ID2 (end pixel ID as long integer; calendar index)</br> time (travel time between ID1 and ID2, in minutes)</br> nd (number of durations and flow rates)</br> durations (vector of durations in minutes)</br> flow rates (vector of discharges in m^3/sec)</br></br>Canals are currently assumed to be lossless, so that the flow rates at the two ends are identical, but lagged by the travel time. </br>The behavior of this component is controlled with a configuration (CFG) file, which may point to other files that contain input data. Here is a sample configuration (CFG) file for this component: </br> Method code: 0</br> Method name: Standard</br> Use sources: 0 Treynor_sources.txt (N/A)</br> Use sinks: 0 Treynor_sinks.txt (N/A)</br> Use canals: 0 Treynor_canals.txt (N/A) Treynor_canals.txt (N/A))
• Model:WACCM-EE  + (GCM initial conditions files (netcdf) files describe initial state of atmosphere up ~km 140)
• Model:TopoToolbox  + (GeoTiff, ESRI ASCII digital elevation model)
• Model:LateralVerticalIncision  + (Geometric parameters of river reach and erosion capacity.)
• Model:DeltaClassification  + (Geometric parameters on delta shapes deriv … Geometric parameters on delta shapes derived from satellite data. </br>To run this code, the following shape files are required:</br></br>• network shapefile, containing the river network extracted from satellite imagery</br>• island shapefile, containing the land masses or islands of the delta</br>• patch shapefile, containing the outline of channelspefile, containing the outline of channels)
• Model:Pllcart3d  + (Geometrical parameters: Nx, Ny, Nz, X1, X2, Y1, Y2, Z1, Z2; Flow parameters: Reynolds, Peclet, Viscosity Ratio; Flags: resume simulation, add wave perturbation.)
• Model:LOADEST  + (Given a time series of streamflow, additional data variables, and constituent concentration, LOADEST assists the user in developing a regression model for the estimation of constituent load (calibration).)
• Model:VIC  + (Global Parameter File user_def.h File Meteorological Forcing Files Soil Parameter File Vegetation Library File Vegetation Parameter File (Optional) Initial State File (Optional) Elevation Band File (Optional) Lake/Wetland Parameter File)
• Model:SETTLE  + (Grain size and density)
• Model:GroundwaterDupuitPercolator  + (Gridded elevation, aquifer base elevation. Hydraulic conductivity, porosity, recharge.)
• Model:Bedrock Fault Scarp  + (HILLSLOPE_LENGTH: length of hillslope, in … HILLSLOPE_LENGTH: length of hillslope, in meters</br>NUMBER_OF_NODES: number of model nodes (initially)</br>EROSION_RATE: slope-normal erosion rate in m/yr</br>THRESHOLD_SLOPE: threshold slope angle (m/m)</br>THROW_RATE: fault throw rate, meters per year</br>FAULT_DIP: fault dip angle, degrees</br>SEISMIC_INTERVAL: Time interval between earthquakes, in years</br>RUN_DURATION: duration of run in years</br>DT: time step duration in years</br>OPT_ERO_VAR: option for time variation in erosion rate</br>AMPLITUDE: amplitude of sinusoidal variation (m/yr)</br>PERIOD: period of sinusoidal variation (yr)</br>PHASE: phase offset for sinusoidal variation (degrees)</br>DEL18O_FILENAME: name of file containing oxygen isotope curve</br>DEL18O_POWER: exponent</br>MIN_ERORATE:</br>OPT_PLOT: option for plotting</br>OPT_EPS_PLOT: option for output to .eps file</br>PLOT_INTERVAL: time interval for plotting, in yearsRVAL: time interval for plotting, in years)
• Model:Zscape  + (INTEGER NXPROB INTEGER TIMESTEPS double pr … INTEGER NXPROB</br>INTEGER TIMESTEPS</br>double precision DIFFUSION</br>double precision DELX,DELT</br>* PARAMETER (NXPROB=1000), c dimension of problem grid</br>* PARAMETER (TIMESTEPS=50000), c number of time steps</br>* PARAMETER (DIFFUSION=1d-3), c metres/year - a very high diffusion value</br>* PARAMETER (DELX=0.1d0), c grid spacing in metres</br>* PARAMETER (DELT=1d0), c time step in yearsPARAMETER (DELT=1d0), c time step in years)
• Model:SNAC  + (In XML format, the following groups of par … In XML format, the following groups of parameters are specified:</br></br>simulation control group: total model time, time step, damping, etc.</br>plugins: elasticity, viscoelasticity, temperature solver, etc.</br>domain description group: domain size, element numbers, etc.</br>initial and boundary conditions groupetc. initial and boundary conditions group)
• Model:CoastMorpho2D  + (Initial bathymetry Boundary conditions Time series of waves, wind, storm surges Various hydrodynamics and sedimentary parameters)
• Model:SBEACH  + (Initial beach profiles, time series of storm wave heights, periods, and storm water levels)
• Model:CMFT  + (Initial bottom configuration, wind and tide characteristics, sea level rise rate, water column sediment concentration at the boundary.)
• Model:Shoreline  + (Initial coastline curve (array of xy pairs), depth of closure, a time series of wind speeds and angles, sediment grainsize, coastal bluff heights, a variety of configuration flags)

• Model:MarshMorpho2D  + (Initial elevation (z) grid with cell type (A))

• Model:MARSSIM  + (Initial elevation file. File specifying boundary conditions, run time, process options, and parameter values.)
• Model:Erode  + (Initial land surface (several built-in opt … Initial land surface (several built-in options), number of timesteps, DEM grid dimensions, DEM grid cell dimensions, R = "geomorphic" rainrate (m/yr), U=uplift rate (mm/yr), BLR = base-level lowering rate (mm/yr), Kf="erodibility coefficient (m^3/yr)^(1-m), m = area/discharge exponent, n = slope exponent, p = area-discharge exponent, toggles for different types of boundary conditions (e.g. periodic), DEM georeferencing info (bounding box, pixel geometry, etc.) info (bounding box, pixel geometry, etc.))
• Model:GPM  + (Initial topography. Initial subsurface la … Initial topography.</br></br>Initial subsurface layering, if any.</br>Properties of existing rocks/sediments.</br>Sea-level change curve.</br>Sources of flow and sediment, sources of wave action, boundary conditions Externally imposed vertical tectonics as a function of horizontal position and timea function of horizontal position and time)
• Model:HBV  + (Input data are observations of precipitation, air temperature and estimates of potential evapotranspiration.)
• Model:AlluvStrat  + (Input file: channel width and depth, a few others)
• Model:ESCAPE  + (Input files for eSCAPE are based on YAML s … Input files for eSCAPE are based on YAML syntax. </br></br>domain: definition of the unstructured grid containing the vtk grid filename and the associated field (here called Z) as well as the flow direction method to be used flowdir that takes an integer value between 1 (for SFD) and 12 (for Dinf) and the boundary conditions (bc: ‘flat’, ‘fixed’ or ‘slope’)</br>time: the simulation time parameters defined by start, end, tout (the output interval) and dt (the internal time-step).</br>Follows the optional forcing conditions:</br></br>sea: the sea-level declaration with the relative sea-level position (m) and the sea-level curve which is a file containing 2 columns (time and sea-level position).</br>climatic & tectonic have the same structure with a sequence of events defined by a starting time (start) and either a constant value (uniform) or a map.</br>Then the parameters for the surface processes to simulate:</br></br>spl: for the stream power law with a unique parameter Ke representing the The erodibility coefficient which is scale-dependent and its value depend on lithology and mean precipitation rate, channel width, flood frequency, channel hydraulics. It is worth noting that the coefficient m and n are fixed in this version and take the value 0.5 & 1 respectively.</br>diffusion: hillslope, stream and marine diffusion coefficients. hillslopeK sets the simple creep transport law which states that transport rate depends linearly on topographic gradient. River transported sediment trapped in inland depressions or internally draining basins are diffused using the coefficient (streamK). The marine sediment are transported based on a diffusion coefficient oceanK. The parameter maxIT specifies the maximum number of steps used for diffusing sediment during any given time interval dt.</br>Finally, you will need to specify the output folder:</br></br>output: with dir the directory name and the option makedir that gives the possible to delete any existing output folder with the same name (if set to False) or to create a new folder with the give dir name plus a number at the end (e.g. outputDir_1 if set to True)umber at the end (e.g. outputDir_1 if set to True))
• Model:LTRANS  + (Input files: # the NetCDF files from the R … Input files:</br># the NetCDF files from the ROMS hydrodynamic model</br># a comma delimited file that contains the particle locations, </br># comma delimited files that contain habitat boundaries for the Settlement Module. The latter is only needed if the Settlement Module is turned on.ded if the Settlement Module is turned on.)
• Model:IDA  + (Input flow directions: 8 bit unsigned in … Input flow directions:</br> 8 bit unsigned integers</br></br> The numbers corresponding to each of the 9 possible flow directions are</br> shown below:</br></br> 32 64 128</br></br> 16 0 1</br></br> 8 4 2</br></br> So a cell with the value '1' means that the flow in that cell goes to the</br> East, while a value of '32' means that the cell's flow goes to the</br> North West. The value '0' implies that the cell is a sink and flow does not</br> leave it</br></br> Row major order is used.not leave it Row major order is used.)
• Model:QDSSM  + (Input is in the form of values per time st … Input is in the form of values per time step for the following variables: files of rain fall, river inlet, sea-level, substratum thickness, tectonics, subsidence, while the model is calibrated through environmental coefficients, threshold slopes, threshold discharge, and set for interval time steps, number of time steps, environmental coefficients (m2/yr) and substratum grain size.icients (m2/yr) and substratum grain size.)
• Model:CVPM  + (Input parameters are provided through several user-supplied files (see the CVPM modeling system user's guide).)
• Model:DHSVM  + (Input parameters are: * Digital Elevation … Input parameters are:</br>* Digital Elevation Model (DEM) of the basin</br>* Soil textural and hydraulic information</br>* Vegetation information</br>* Meteorological conditions at a subdaily timestep, in particular precipitation, air temperature, humidity, wind speed, incoming shortwave radiation and incoming longwave radiation</br>* Information about the stream and road network (location, width, etc.)m and road network (location, width, etc.))
• Model:Meander Centerline Migration Model  + (Input parameters belong to five families: … Input parameters belong to five families:</br>* parameters related to flow field</br>* parameters related to the floodplain structure</br>* parameters related to the river geometry</br>* parameters related to the time marching of the simulation</br>* parameters related to the output printing parameters related to the output printing)
• Model:Spbgc  + (Input parameters: * Geometrical parameters: Nx, Ny, domain size * Flow Parameters: Reynolds, Peclet * Particle Parameters: Settling velocities. The complete list of input parameters is set and described in the file input.inp)
• Model:WASH123D  + (Input parameters: # Geomety in terms of f … Input parameters:</br># Geomety in terms of finite element mesh</br># matreial properties,</br># initila conditions,</br># boundary conditions,</br># meteogoligcal data, and</br># reaction networks for biogeochemical transport. </br></br>Detailed input/output refers to Yeh et al., 2005 Technical Report on WASH123D et al., 2005 Technical Report on WASH123D)
• Model:CREST  + (Input parameters: * DEM * Precipitation * Potential Evapotranspiration)
• Model:Gvg3Dp  + (Input parameters: *Geometrical parameters: Nx, Ny, Nz. *Grid: Uniform or nonuniform. *Flow Parameters: Reynolds, Peclet *Particle Parameters: Settling velocities. *Flags: Output writing flags. Inflow/Outflow to the domain flags.)
• Model:CosmoLand  + (Input: *Landslide: recurrence interval, si … Input:</br>*Landslide: recurrence interval, size parameters</br>*Cosmogenic: production rate, decay rate, attenuation, density diffusive erosion rate drainage basin size, critical drainage area for a channel</br>*River channel scaling parameters: width, sediment depth, drainage densitys: width, sediment depth, drainage density)
• Model:LEMming2  + (Inputs include grid definitions, erosion rule parameters, uplift time series, stratigraphic geometry, and rock type and rockfall debris erodibility.)
• Model:SNOWPACK  + (It requires the following meteorological p … It requires the following meteorological parameters:</br>* air temperature (TA)</br>* relative humidity (RH)</br>* wind speed (VW)</br>* incoming short wave radiation (ISWR) and/or reflected short wave radiation (RSWR)</br>* incoming long wave radiation (ILWR) and/or surface temperature (TSS)</br>* precipitation (PSUM) and/or snow height (HS)</br>* ground temperature (TSG, if available. Otherwise, you will have to use MeteoIO's data generators to generate a value) or geothermal heat flux</br>* snow temperatures at various depths (TS1, TS2, etc if available and only for comparisons, see section Snow and/or soil temperatures)see section Snow and/or soil temperatures))
• Model:Gc2d  + (Landscape elevation, ELA with time)
• Model:LONGPRO  + (Length of reach, distance between nodes, t … Length of reach, distance between nodes, timestep, number of timesteps, median grain size, elevation of the water surface, slope of initial river bed, Qmax, Xmax, mainning N, Initial elevation, node along X-as at which tectonic elev. Changes start, sediment conc. of lateral inflow, mass feed rate at upstream boundary,flow, mass feed rate at upstream boundary,)
• Model:Subside  + (Loading distribution, EET, Mantle viscosity)
• Model:Inflow  + (Main input parameters: * River velocity, width, depth, and sediment concentration. * Bathymetry)
• Model:Sakura  + (Main input parameters: * River velocity, width, depth, and sediment concentration * Bathymetry)
• Model:WSGFAM  + (Main inputs are bathymetry, riverine sediment discharge time-series, and ambient wave and current time-series. Critical velocity for sea bed erosion, bottom drag coefficient and critical bulk Richardson number can also be adjusted.)