Models all extended table
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All models (297)
Program | Description | Developer | Download | PyMT |
---|---|---|---|---|
1D Particle-Based Hillslope Evolution Model | 1D probabilistic, particle-based model of hillslope evolution for studying hillslope equilibration and response to perturbations. | Calvert, Jacob | ||
1DBreachingTurbidityCurrent | 1D Breaching Turbidity current model for generating continuous turbidity currents | Eke, Esther | ||
2DFLOWVEL | Tidal & wind-driven coastal circulation routine | Slingerland, Rudy | ||
ACADIA | A finite element formulation of the non-conservative form of the vertically integrated advection/diffusion/reaction (ADR) equation | Gentleman, Wendy | ||
ADCIRC | Coastal Circulation and Storm Surge Model | Luettich, Rick | ||
ALFRESCO | Alaskan Frame‐based Ecosystem Code | Bennett, Alec | ||
AR2-sinuosity
|
Generates planforms for single-thread channel using a second-order autoregressive model | Limaye, Ajay | ||
ATS (The Advanced Terrestrial Simulator)
|
The Advanced Terrestrial Simulator (formerly sometimes known as the Arctic Terrestrial Simulator) is a code for solving ecosystem-based, integrated, distributed hydrology. | Coon, Ethan | ||
AeoLiS | AeoLiS is a process-based model for simulating aeolian sediment transport in situations where supply-limiting factors are important, like in coastal environments. | Hoonhout, Bas | ||
AlluvStrat | Rules-based model to generate a 2-dimensional cross section of alluvial stratigraphy based on fluvial processes | Wickert, Andy | ||
Alpine3D | 3D model of alpine surface processes | Bavay, Mathias | ||
Anuga | ANUGA is a hydrodynamic modelling tool that allows users to model realistic flow problems in complex 2D geometries. | Habili, Nariman | ||
AnugaSed | Add-on package to ANUGA with modules for sediment transport and vegetation drag | Perignon, Mariela | ||
ApsimX
|
The Agricultural Production Systems sIMulator (APSIM) | Holzworth, Dean | ||
AquaTellUs | Fluvial-dominated delta sedimentation model | Overeem, Irina | ||
Auto marsh
|
Cellula automata model for salt marsh evolution with variable soil resistance under wind waves attack | Leonardi, Nicoletta | ||
Avulsion
|
Stream avulsion model | Hutton, Eric | ||
BEDLOAD | Bedload transport model | Slingerland, Rudy | ||
BOM | Bergen Ocean Model | Berntsen, Jarle | ||
BRaKE
|
Computes evolution of a bedrock river longitudinal profile in the presence of large, hillslope-derived blocks. | Shobe, Charles | ||
Badlands | Basin and landscape dynamics | Salles, Tristan | ||
Barrier Inlet Environment (BRIE) Model | Coastal barrier island transgression model | Nienhuis, Jaap | ||
Barrier3D | A spatially explicit model of coastal barrier evolution | Reeves, Ian | ||
BarrierBMFT | Barrier-Bay-Marsh-Forest Transect Coupled Model Framework | Reeves, Ian | ||
Bedrock Fault Scarp | This is a two-dimensional numerical model that computes the topographic evolution of the facet slope in the footwall of an active normal fault. | Tucker, Greg | ||
Bifurcation | Flow-partitioning and avulsion in a river delta bifurcation | Salter, Gerard | ||
Bing | Submarine debris flows | Hutton, Eric | ||
Bio | Biogenic mixing of marine sediments | Hutton, Eric | ||
BlockLab
|
BlockLab computes landscape evolution in the presence of large blocks of rock on hillslopes and in channels. | Shobe, Charles | ||
CAESAR Lisflood
|
Caesar Lisflood is a morphodynamic / Landscape evolution model that simulates erosion and deposition in river catchments and reaches over time scales from hours to 1000's of years. | Coulthard, Tom | ||
CAM-CARMA | A GCM for Titan that incorporates aerosols | Larson, Eric | ||
CBOFS2 | The Second Generation Chesapeake Bay Operational Forecast System (CBOFS2): A ROMS‐Based Modeling System | Lanerolle, Lyon | ||
CEM | Coastline evolution model | Murray, A. Brad | ||
CHILD | Landscape Evolution Model | Tucker, Greg | ||
CICE | Los Alamos sea ice model | Hunke, Elizabeth | ||
CLUMondo | The CLUMondo model is a spatially explicit and dynamics land system change model | Verburg, Peter | ||
CMFT | Coupled salt Marsh - tidal Flat Transect model | Mariotti, Giulio | ||
CREST | The Coupled Routing and Excess STorage (CREST) model is a distributed hydrologic model developed to simulate the spatial and temporal variation of atmospheric, land surface, and subsurface water fluxes and storages by cell-to-cell simulation. | Wang, Jiahu | ||
CVFEM Rift2D | multi-physics numerical model that simulates rock deformation, fluid flow, solute transport and heat transfer in response to ice sheet loading of multiple cycles | Zhang, Yipeng | ||
CVPM
|
Multidimensional heat-transfer modeling system for permafrost with advanced unfrozen water physics | Clow, Gary | ||
Caesar | Cellular landscape evolution model | Coulthard, Tom | ||
CarboCAT | Carbonate cellular automatacyclicity | Burgess, Peter | ||
ChannelProfiler | The ChannelProfiler extracts and plots channel networks from a landlab grid. | Barnhart, Katy | ||
ChesROMS | Chesapeake Bay ROMS Community Model (ChesROMS), special case of ROMS | Long, Wen | ||
Chi analysis tools
|
Tool for examining channel profiles in chi-elevation space using the integral method of channel analysis | Mudd, Simon | ||
ChiFinder | Calculate Chi Indices | Hobley, Daniel | ||
Cliffs | Numerical model to compute tsunami propagation and runup on land in the shallow-water approximation | Tolkova, Elena | ||
CoAStal Community-lAnDscape Evolution (CASCADE) model
|
A coupled landscape and human-dynamics modeling framework for barrier evolution | Anarde, Katherine | ||
Coastal Dune Model | Evolution of Coastal Foredunes | Durán Vinent, Orencio | ||
Coastal Landscape Transect Model (CoLT) | Geomorphic and carbon evolution of a bay-marsh-forest coastal transect | Valentine, Kendall | ||
CosmoLand | 2-D model tracking cosmogenic nuclides and mixing in landslide terrain | Yanites, Brian | ||
Cross Shore Sediment Flux | Cross-Shore Sediment Flux Equations | Ortiz, Alejandra | ||
CryoGrid3 | CryoGrid 3 is a simple land-surface scheme dedicated to modeling of ground temperatures in permafrost environments. | Westermann, Sebastian | ||
Cyclopath | A 2D/3D model of carbonate cyclicity | Burgess, Peter | ||
DELTA | Simulates circulation and sedimentation in a 2D turbulent plane jet and resulting delta growth | Slingerland, Rudy | ||
DFMFON
|
Spatially-Explicit Mangrove-Mudflat Dynamic Model | Beselly, Sebrian | ||
DHSVM | DHSVM is a distributed hydrologic model that explicitly represents the effects of topography and vegetation on water fluxes through the landscape. | DHSVM, Administrator | ||
DLBRM | Distributed Large Basin Runoff Model | Croley, Thomas | ||
DR3M | Distributed Routing Rainfall-Runoff Model--version II | U.S., Geological Survey | ||
DROG3D | 3-DIMENSIONAL DROGUE TRACKING ALGORITHM FOR A FINITE ELEMENT GRID WITH LINEAR FINITE ELEMENTS | Blanton, Brian | ||
Delft3D | 3D hydrodynamic and sediment transport model | Delft3D, Support | ||
DeltaRCM | River delta formation and evolution model with channel dynamics | Liang, Man | ||
DeltaRCM Vegetation | Delta-building model DeltaRCM expanded to include vegetation | Lauzon, Rebecca | ||
DeltaSIM | Process-response model simulating the evolution and stratigraphy of fluvial dominated deltaic systems | Hoogendoorn, Bob | ||
Demeter | Demeter - A Land Use and Land Cover Change Disaggregation Model | Vernon, Chris | ||
DepthDependentTaylorDiffuser | This component implements a depth-dependent Taylor series diffusion rule, combining concepts of Ganti et al. (2012) and Johnstone and Hilley (2014). | Glade, Rachel | ||
DetachmentLtdErosion | Simulate detachment limited sediment transport. | Adams, Jordan | ||
Diffusion | Diffusion of marine sediments due to waves, bioturbation | Hutton, Eric | ||
Dorado | A Python package for simulating passive particle transport in shallow-water flows | Hariharan, Jayaram | ||
DynEarthSol3D | DynEarthSol3D is a finite element solver that models the momentum balance and the heat transfer of elasto-visco-plastic material in the Lagrangian form. | Tan, Eh | ||
ECSimpleSnow | A simple snow model | Wang, Kang | ||
EF5 | Ensemble Framework For Flash Flood Forecasting | Flamig, Zac | ||
ELCIRC | Eulerian-Lagrangian CIRCulation | Zhang, Yinglong | ||
ENTRAIN | Simulates critical shear stress of median grain sizes | Slingerland, Rudy | ||
ENTRAINH | Simulates critical shields theta for median grain sizes | Slingerland, Rudy | ||
ESCAPE | parallel global-scale landscape evolution model | Salles, Tristan | ||
Ecopath with Ecosim
|
Ecopath with Ecosim (EwE) is an ecological modeling software suite for personal computers | Christensen, Villy | ||
Elv-GST | Numerical 1D research code Elv applied to gravel-sand transitions | Blom, Astrid | ||
Erode | Fluvial landscape evolution model | Peckham, Scott | ||
ErosionDeposition
|
Landlab component for fluvial erosion/deposition. | Shobe, Charles | ||
ExponentialWeatherer | Exponential soil production function in the style of Ahnert (1976) | Glade, Rachel | ||
FLDTA | Simulates flow characteristics based on gradually varied flow equation | Slingerland, Rudy | ||
FUNDY | a 3-D diagnostic model for continental shelf circulation studies | Naimie, Christopher | ||
FUNWAVE | Fully Nonlinear Boussinesq Wave Model | Kirby, Jim | ||
FVCOM | The Unstructured Grid Finite Volume Coastal Ocean Model | Chen, Changsheng | ||
FVshock | Finite Volume two-dimensional shock-capturing model. | Canestrelli, Alberto | ||
FastscapeEroder | Compute fluvial erosion using stream power theory (“fastscape” algorithm) | Hobley, Daniel | ||
FineSed3D | A turbulence-resolving numerical model for fine sediment transport in bottom boundary layer | Cheng, Zhen | ||
Flexure | Deform the lithosphere with 1D or 2D flexure. | Hutton, Eric | ||
Frost Model
|
Frost model predicts the likelihood of occurrence of permafrost in the land surface based on the monthly temperature distribution | Overeem, Irina | ||
GEOMBEST | Geomorphic Model of Barrier, Estuarine, and Shoreface Translations | Moore, Laura | ||
GEOMBEST++ | Geomorphic model of barrier, estaurine, and shoreface translations plus dynamic marsh plus waves | Lauzon, Rebecca | ||
GEOMBEST++Seagrass | Geomorphic Model of Barrier, Estuarine, and Shoreface Translations + Marsh + Seagrass | Reeves, Ian | ||
GEOMBEST-Plus | 2D cross-shore geomorphological model of barrier island and marsh response to sea level rise. | Walters, David | ||
GEOtop | Distributed hydrological model, water and energy budgets | Rigon, Riccardo | ||
GFlex | Multiple solution methods for isostasy and lithospheric flexure | Wickert, Andy | ||
GIPL | GIPL(Geophysical Institute Permafrost Laboratory) is an implicit finite difference one-dimensional heat flow numerical model. | Jafarov, Elchin | ||
GISS AOM | GISS Atmosphere-Ocean Model | Rind, David | ||
GISS GCM ModelE | GISS GCM ModelE | Schmidt, Gavin | ||
GLUDM | Global future agricultural land use dynamics model | Cohen, Sagy | ||
GNE | Set of biogeochemical sub-models that predicts river export | Seitzinger, Sybil | ||
GOLEM | Landscape evolution model | Tucker, Greg | ||
GRLP
|
Evolves gravel-bed river long profiles | Wickert, Andrew | ||
GSFLOW | Ground-water and Surface-water FLOW model | Markstrom, Steve | ||
GST-extendedmodel | Extended GST model: combination of an analytical GST migration model combined with closure relations based on the assumption of quasi-equilibrium conditions | Blom, Astrid | ||
Gc2d | Glacier / ice sheet evolution model | Kessler, Mark | ||
GeoClaw
|
Depth-averaged fluid dynamics for modeling geophysical flows and wave propagation | LeVeque, Randall | ||
Glimmer-CISM | Dynamic thermo-mechanical ice sheet model | Hagdorn, Magnus | ||
Gospl | Global Scalable Paleo Landscape Evolution | Salles, Tristan | ||
GrainHill
|
Cellular automaton model of hillslope evolution | Tucker, Gregory | ||
GreenAmptInfiltrationModel | The Green-Ampt method of infiltration estimation. | Jiang, Peishi | ||
GroundwaterDupuitPercolator | The GroundwaterDupuitPercolator solves the Boussinesq equation for flow in an unconfined aquifer over an impermeable aquifer base and calculates groundwater return flow to the surface. | Litwin, David | ||
GullyErosionProfiler1D | This model is designed to simulate longitudinal profiles with headward advancing headcuts. | Rengers, Francis | ||
HBV | HBV model is a rainfall-runoff model | Craven, John | ||
HIM | Hallberg Isopycnal Model | Hallberg, Robert | ||
HYPE | Hydrological model for simulation of water and water quality over time | SMHI, -- | ||
HexWatershed | A mesh independent flow direction model for hydrologic models | Liao, Chang | ||
Hogback | Evolution of a hogback | Glade, Rachel | ||
HyLands
|
The HyLands model simulates the impact of bedrock landslides on topographic evolution and sediment dynamics. | Campforts, Benjamin | ||
HydroCNHS | HydroCNHS, a Python Package of Hydrological Model for Coupled Natural–Human Systems | Lin, Chung-Yi | ||
HydroRaVENS | Linear-reservoir hydrological model with snowpack and evapotranspiration | Wickert, Andrew | ||
HydroTrend | Climate driven hydrological transport model | Kettner, Albert | ||
Hyper | 2D Turbidity Current model | Imran, Jasim | ||
ISSM | Ice Sheet System Model (ISSM) | Larour, Eric | ||
IceFlow | 2D semi-implicit shallow ice approximation glacier model | Wickert, Andy | ||
Inflow | Steady-state hyperpycnal flow model | Hutton, Eric | ||
Instructed Glacier Model
|
The Instructed Glacier Model (IGM) simulates the ice dynamics, surface mass balance, and its coupling through mass conservation to predict the evolution of glaciers, icefields, or ice sheets | Jouvet, Guillaume | ||
KWAVE | A model representing infiltration, interception, and runoff using the kinematic wave approximation | McGuire, Luke | ||
Kudryavtsev Model
|
Permafrost Active Layer Thickness Model based on Kudryavtsev's parametrization | Overeem, Irina | ||
LEMming | LEMming landscape evolution model: a 2-D, regular-grid, rules-based, hybrid finite-difference / cellular automaton model that is designed to explore the effect of multiple rock types on landscape evolution. | Ward, Dylan | ||
LEMming2 | 2D model that simulates the retreat of hard-capped cliffs | Ward, Dylan | ||
LISFLOOD | LISFLOOD - a distributed hydrological rainfall-runoff model | de Roo, Ad | ||
LITHFLEX1 | Lithospheric flexure solution | Furlong, Kevin | ||
LITHFLEX2 | Lithospheric flexure solution for a broken plate | Furlong, Kevin | ||
LOADEST | Software for estimating constituent loads in streams and rivers | Runkel, Rob | ||
LONGPRO | Dynamic evolution of longitudinal profiles | Slingerland, Rudy | ||
LTRANS | The Larval TRANSport Lagrangian model (LTRANS) is an off-line particle-tracking model that runs with the stored predictions of a 3D hydrodynamic model, specifically the Regional Ocean Modeling System (ROMS). | North, Elizabeth | ||
LaMEM | LaMEM - Lithosphere and Mantle Evolution Model | Popov, Anton | ||
Landlab | Python software framework for writing, assembling, and running 2D numerical models | Tucker, Greg | ||
Landslides | Landlab component that simulates landslide probability of failure as well as mean relative wetness and probability of saturation. | Strauch, Ronda | ||
LateralVerticalIncision
|
Geometric model to explore autogenic increase of vertical incision rate in entrenching alluvial rivers. | Malatesta, Luca | ||
LinearDiffuser | Landlab component that models soil creep as a linear diffusion process | Tucker, Greg | ||
LuSS
|
A set of MATLAB functions to model how luminescence evolves in different geomorphic scenarios. | Brown, Nathan | ||
LumSoilMixer | This is a model to simulate the non-dimensionalized luminescence in a mixing soil. | Gray, Harrison | ||
MARM5D
|
Landscape-scale soil evolution model | Cohen, Sagy | ||
MARSSIM | Landform evolution model | Howard, Alan | ||
MARSSIM V4
|
MARSSIM terrestrial and planetary Landform Evolution Model | Howard, Alan | ||
MCPM
|
A stand alone model for the morphological evolution of an idealized transect across a marsh channel-and-platform. | Mariotti, Giulio | ||
MICOM | Miami Isopycnic Coordinate Ocean Model | Bleck, Rainer | ||
MIDAS | Coupled flow- heterogeneous sediment routing model | Slingerland, Rudy | ||
MITgcm | The MITgcm (MIT General Circulation Model) is a numerical model designed for study of the atmosphere, ocean, and climate. | Lovenduski, Nicole | ||
MODFLOW | MODFLOW is a three-dimensional finite-difference ground-water model | Barlow, Paul | ||
MODFLOW 6
|
MODFLOW 6 is an object-oriented program and framework developed to provide a platform for supporting multiple models and multiple types of models within the same simulation | Hughes, Joseph | ||
MOM6 | MOM6 is the latest generation of the Modular Ocean Model which is a numerical model code for simulating the ocean general circulation. | User community, MOM6 | ||
MRSAA
|
Macro-roughness model framework for treating erosion, bed cover, and sediment transport in bedrock river channels. | Zhang, Li | ||
Manningseq-bouldersforpaleohydrology | Matlab® code for paleo-hydrological flood flow reconstruction in a fluvial channel | Huber, Marius | ||
MarshMorpho2D | 2D long-term marsh evolution model based on tidal dispersion | Mariotti, Giulio | ||
MarshPondModel | 2D marsh evolution model focused on pond dynamics | Mariotti, Giulio | ||
Meander Centerline Migration Model
|
Simulation of the long-term migration of meandering rivers flowing above heterogeneous floodplains | Bogoni, Manuel | ||
Meanderpy | A simple kinematic model of meandering | Sylvester, Zoltan | ||
Mixed bedrock-alluvial morphodynamic | Alluvial morphodynamics of bedrock reaches | Jafarinik, Sadegh | ||
Mocsy | Routines to model the ocean carbonate system | Orr, James | ||
Morphodynamic gravel bed | Morphodynamic evolution of gravel bed rivers | Jafarinik, Sadegh | ||
Mosartwmpy | Model for Scale Adaptive River Transport with Water Management in Python | Thurber, Travis | ||
Mrip | Mrip is a self-organization type model for the formation and dynamics of megaripples in the nearshore. | Gallagher, Edith | ||
NUBBLE | A turbulent boundary layer model for the linearized shallow water equations | Naimie, Christopher | ||
NearCoM | Nearshore Community Model | Kirby, James | ||
Nitrate Network Model | Nitrate and organic carbon dynamics on a wetland-river network | Czuba, Jonathan | ||
NormalFault | NormalFault implements relative rock motion due to a normal fault. | Barnhart, Katy | ||
OGGM | OGGM is a modular open source model for glacier dynamics | Maussion, Fabien | ||
OTEQ | One-Dimensional Transport with Equilibrium Chemistry (OTEQ): A Reactive Transport Model for Streams and Rivers | Runkel, Rob | ||
OTIS | One-Dimensional Transport with Inflow and Storage (OTIS): A Solute Transport Model for Streams and Rivers | Runkel, Rob | ||
OTTAR | Ode To Transient (Ancho de los) Rivers: Transient evolution of river-channel width in response to river discharge and bank and sediment properties. | Wickert, Andrew | ||
OTTER | Evolution of a river profile with dynamic width | Yanites, Brian | ||
OceanWaves | Calculate wave-generated bottom orbital velocities from surface wave parameters | Wiberg, Patricia | ||
Oceananigans.jl | Oceananigans.jl is a fast and friendly ocean-flavored Julia software for simulating incompressible fluid dynamics in Cartesian and spherical shell domains on CPUs and GPUs. | Ramadhan, Ali | ||
OlaFlow
|
Wave generation and active absorption interaction with porous structures framework | Higuera, Pablo | ||
OverlandFlow
|
Component simulating overland flow using a 2-D numerical approximation of the shallow-water equations following the de Almeida et al., 2012 algorithm for storage-cell inundation modeling. | Adams, Jordan | ||
OverlandFlowBates | This component simulates overland flow using the 2-D numerical model of shallow-water flow over topography using the Bates et al. (2010) algorithm for storage-cell inundation modeling. | Adams, Jordan | ||
PHREEQC | PHREEQC version 3 is a computer program written in the C and C++ programming languages that is designed to perform a wide variety of aqueous geochemical calculations | Parkhurst, David | ||
PIHM | PIHM is a multiprocess, multi-scale hydrologic model. | Duffy, Christopher | ||
PISM | Parallel Ice Sheet Model, PISM | Group, Glacier | ||
PRMS | Precipitation-Runoff Modeling System | Leavesley, George | ||
PSTSWM | Parallel Spectral Transform Shallow Water Model | Worley, Patrick | ||
ParFlow | Parallel, high-performance, integrated watershed model | Maxwell, Reed | ||
PerronNLDiffuse | Nonlinear diffusion, following Perron (2011). | Hobley, Daniel | ||
Pllcart3d | 3D numerical simulation of confined miscible flows | Oliveira, Rafael | ||
Plume | Hypopycnal sediment plume | Hutton, Eric | ||
Point-Tidal-flat | Point Model for Tidal Flat Evolution model | Fagherazzi, Sergio | ||
PotentialEvapotranspiration | Calculates potential evapotranspiration | Nudurupati, Sai | ||
Princeton Ocean Model (POM) | POM: Sigma coordinate coastal & basin circulation model | Ezer, Tal | ||
PyDeCe
|
Python model for Dense Current forming eruptions (PyDeCe) is a tool for modeling the dense endmember of pyroclastic density currents generated either by impulsive column collapse or sustained fountaining eruptions. | Ganesh, Indujaa | ||
PyDeltaRCM | Reduced complexity river delta formation and evolution model with channel dynamics | Perignon, Mariela | ||
QTCM | Quasi-equilibrium Tropical Circulation Model | Neelin, David | ||
QUAL2K | A Modeling Framework for Simulating River and Stream Water Quality | Chapra, Steve | ||
QUODDY | A state-of-the-art finite-element computer simulation program for coastal ocean circulation modeling | Lynch, Kristina | ||
RAFEM
|
River Avulsion and Floodplain Evolution Module | Ratliff, Katherine | ||
REF-DIF | Phase-resolving parabolic refraction-diffraction model for ocean surface wave propagation. | Kirby, James | ||
RHESSys | Regional Hydro-Ecologic Simulation System | Tague, christina | ||
ROMS | Regional Ocean Modeling System | Arango, Hernan G. | ||
Rescal-snow | A model of dunes and snow-waves | Kochanski, Kelly | ||
Reservoir | Reservoir: Tools for Analysis, Design, and Operation of Water Supply Storages | Turner, Sean | ||
River Erosion Model
|
An intermediate complexity model for simulating stream channel evolution (years to decades) at the watershed scale. | Lammers, Roderick | ||
River Network Bed-Material Sediment | Bed-material sediment transport and storage dynamics on river networks. | Czuba, Jonathan | ||
River Temperature Model
|
River Temperature Model based on heat balance approach | Overeem, Irina | ||
RiverMUSE
|
Simulates freshwater mussel populations' response to changes in suspended sediment | Schwenk, Jon | ||
SBM | Sorted Bedform Model | Murray, A. Brad | ||
SEA | Southamption--East Anglia | Stevens, David | ||
SELFE | Semi-implicit Eulerian–Lagrangian Finite Element | Zhang, Yinglong | ||
SFINCS | SFINCS, a reduced-physics solver to compute compound flooding in coastal systems due to fluvial, pluvial, tidal, wind- and wave-driven processes | Leijnse, Tim | ||
SIBERIA | SIBERIA simulates the evolution of landscapes under the action of runoff and erosion over long times scales. | Willgoose, Garry | ||
SICOPOLIS | Ice sheet model | Greve, Ralf | ||
SIGNUM
|
SIGNUM (Simple Integrated Geomorphological Numerical Model) is a MAtlab TIN-based landscape evolution model | Capolongo, Domenico | ||
SINUOUS
|
SINUOUS - Meander Evolution Model | Howard, Alan | ||
SLAMM 6.7
|
The Sea Level Affecting Marshes Model (SLAMM) | Clough, Jonathan | ||
SLEPIAN Alpha | Computation of spherical harmonics, Slepian functions, and transforms | Simons, Frederik | ||
SLEPIAN Bravo | Linear inverse problems using spherical harmonics and spherical Slepian functions | Simons, Frederik | ||
SLEPIAN Charlie | Spectral estimation problems using spherical harmonics and spherical Slepian functions | Simons, Frederik | ||
SLEPIAN Delta | Analysis of time-variable gravity from the GRACE satellite mission using spherical harmonics and spherical Slepian functions | Harig, Christopher | ||
SNAC | An updated Lagrangian explicit finite difference code for modeling a finitely deforming elasto-visco-plastic solid in 3D. | Choi, Eunseo | ||
SPACE
|
Landlab component for 2-D calculation of fluvial sediment transport and bedrock erosion | Shobe, Charles | ||
SPARROW | The SPARROW Surface Water-Quality Model | Alexander, Richard | ||
SPHYSICS | Smoothed Particle Hydrodynamics code | Dalrymple, Robert | ||
STORM | Windfield simulator for a cyclone | Slingerland, Rudy | ||
STSWM | NCAR Spectral Transform Shallow Water Model | Hack, James | ||
STVENANT | 1D gradually varied flow routine | Slingerland, Rudy | ||
STWAVE | Steady-State Spectral Wave Model | Smith, Jane | ||
SUSP | Suspended load transport subroutine | Slingerland, Rudy | ||
SWAN | SWAN is a third-generation wave model | SWAN, Team | ||
SWAT | SWAT is a river basin scale model developed to quantify the impact of land management practices in large, complex watersheds. | Arnold, Jeff | ||
SWEHR | A coupled model for infiltration, fluid flow, and sediment transport. | McGuire, Luke | ||
SWMM | Storm Water Management Model | Rossman, Lewis | ||
Sakura | 3 Equation hyperpycnal flow model | Kubo, Yusuke | ||
SedBerg | An iceberg drift and melt model, developed to simulate sedimentation in high-latitude glaciated fjords. | Mugford, Ruth | ||
SedCas | A probabilistic sediment cascade model for sediment production, storage and transfer | Hirschberg, Jacob | ||
SedDepEroder | Compute fluvial erosion using using “tools and cover” theory | Hobley, Daniel | ||
SedFoam-2.0 | A multi-dimensional Eulerian two-phase model for sediment transport (version 2.0) | Chauchat, Julien | ||
Sedflux | Basin filling stratigraphic model | Hutton, Eric | ||
Sedtrans05 | Sediment transport model for continental shelf and estuaries | Neumeier, Urs | ||
SiStER | An easy-to-use MATLAB code to simulate long-term lithosphere and mantle deformation. | Olive, Jean-Arthur | ||
SoilInfiltrationGreenAmpt
|
Landlab component that calculates soil infiltration based on the Green-Ampt solution. | Rengers, Francis | ||
SoilMoisture | Compute the decay of soil moisture saturation at storm-interstorm time period | Nudurupati, Sai | ||
SpeciesEvolver | Evolve life in a landscape. | Lyons, Nathan | ||
StreamPowerSmoothThresholdEroder | Compute fluvial erosion using stream power theory with a numerically smoothed threshold | Tucker, Greg | ||
Subside | Flexure model | Hutton, Eric | ||
Sun fan-delta model | Fan-delta and alluvial fan landscape evolution model | Limaye, Ajay | ||
Symphonie
|
3D primitive equation ocean model | Marsaleix, Patrick | ||
TAo | tAo is a software designed to model the interplay between lithosphere flexure and surface transport (erosion/sedimentation), particularly during the formation of orogens and foreland sedimentary basins (see details). | Garcia Castellanos, Daniel | ||
TISC
|
TISC integrates quantitative models of lithospheric flexure, fault deformation, and surface mass transport (erosion/transport/sedimentation) along drainage networks. | Garcia Castellanos, Daniel | ||
TOPMODEL | Physically based, distributed watershed model that simulates hydrologic fluxes of water through a watershed | Beven, Keith | ||
TURBINS | An immersed boundary, Navier–Stokes code for the simulation of gravity and turbidity currents interacting with complex topographies. | Nasr-Azadani, Mohamad | ||
TaylorNonLinearDiffuser | Model non-linear soil creep after Ganti et al. (2012) | Glade, Rachel | ||
Terrainbento
|
A Python package for multi-model analysis in long-term drainage basin evolution | Barnhart, Katy | ||
Terrapin | Build and destroy strath and fill terraces | Wickert, Andy | ||
ThawLake1D | 1-D numerical model of permafrost and subsidence processes. | Matell, Nora | ||
The TELEMAC system
|
a powerful integrated modeling tool for use in the field of free-surface flows. | TELEMAC support team, - | ||
TopoFlow | Spatially-distributed, D8-based hydrologic model | Peckham, Scott | ||
TopoFlow-Channels-Diffusive Wave | Diffusive Wave process component for flow routing in a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Channels-Dynamic Wave | Dynamic Wave process component for flow routing in a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Channels-Kinematic Wave | Kinematic Wave process component for flow routing in a D8-based, spatial hydrologic model. | Peckham, Scott | ||
TopoFlow-Diversions | Diversions component for a D8-based, spatial hydrologic model. | Peckham, Scott | ||
TopoFlow-Evaporation-Energy Balance | Evaporation process component (Energy Balance method) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Evaporation-Priestley Taylor | Evaporation process component (Priestley-Taylor method) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Evaporation-Read File | Evaporation process component (read from file method) for a spatially-distributed hydrologic model. | Peckham, Scott | ||
TopoFlow-Infiltration-Green-Ampt | Infiltration process component (Green-Ampt method) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Infiltration-Richards 1D | Infiltration process component (Richards 1D method) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Infiltration-Smith-Parlange | Infiltration process component (Smith-Parlange method) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Meteorology | Meteorology process component for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Saturated Zone-Darcy Layers | Saturated Zone process component (Darcy's law, multiple soil layers) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Snowmelt-Degree-Day | Snowmelt process component (Degree-Day method) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
TopoFlow-Snowmelt-Energy Balance | Snowmelt process component (Energy Balance method) for a D8-based, spatial hydrologic model | Peckham, Scott | ||
Tracer dispersion calculator | The model computes the streamwise and vertical dispersal of a patch of tracers in a gravel bed river | Viparelli, Enrica | ||
TransportLengthHillslopeDiffuser | Transport length hillslope diffusion. | Mouchene, Margaux | ||
TwoPhaseEulerSedFoam
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A four-way coupled two-phase Eulerian model for sediment transport | Cheng, Zhen | ||
UEB | The Utah Energy Balance (UEB) Grid snowmelt model | Tarboton, David | ||
UMCESroms | Chesapeake Bay Application, special case of Regional Ocean Modeling System (ROMS) | Li, Yun | ||
Underworld2 | Underworld2 is an open-source, particle-in-cell finite element code tuned for large-scale geodynamics simulations. | Moresi, Louis | ||
VIC | VIC (Variable Infiltration Capacity) is a macroscale hydrologic model that solves full water and energy balances, originally developed by Xu Liang at the University of Washington. | Lettenmaier, Dennis | ||
VegCA | Landlab component that simulates inter-species plant competition using a 2D cellular automata model. | Nudurupati, Sai | ||
Vegetation | Model plant dynamics using multiple representative plant species | Nudurupati, Sai | ||
WACCM Dust-Sulfur | Whole atmosphere module of sulfate aerosols. | Neely, Ryan | ||
WACCM-CARMA | atmospheric/aerosol microphysical model | English, Jason | ||
WACCM-EE | GCM for deep paleoclimate studies | Wolf, Eric | ||
WAVEREF | Wave refraction routine | Slingerland, Rudy | ||
WAVEWATCH III ^TM | Spectral wind wave model | Tolman, Hendrik | ||
WBM-WTM
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Water Balance/Transport Model | Fekete, Balazs | ||
WBMsed | Global sediment flux and water discharge model. | Cohen, Sagy | ||
WDUNE | GUI implementation of the Werner (1995) cellular automata aeolian dune model | Barchyn, Tom | ||
WILSIM | Landscape evolution model | Luo, Wei | ||
WINDSEA | Deep water significant wave height and period simulator during a hurricane routine | Slingerland, Rudy | ||
WOFOST | WOFOST (WOrld FOod STudies) is a simulation model for the quantitative analysis of the growth and production of annual field crops. | Boogaard, Hendrik | ||
WRF | Weather Research and Forecasting Model | Skamarock, Bill | ||
WRF-Hydro
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The WRF-Hydro® Modeling System, an open-source community model, is used for a range of projects, including flash flood prediction, regional hydroclimate impacts assessment, seasonal forecasting of water resources, and land-atmosphere coupling studies. It produces forecasts and analyses for all major terrestrial water-cycle components: Precipitation, Streamflow, Soil moisture, Snowpack, Flooding, Groundwater. | McAllister, Molly | ||
WSGFAM | Wave and current supported sediment gravity flow model | Friedrichs, Carl | ||
Wetland3P
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A 3-point dynamic model for the morphological evolution of a backbarrier basin composed by marshes and mudflats | mariotti, giulio | ||
XBeach | Morphological changes, nearshore currents, wave propagation and sediment transport model | Roelvink, Dano | ||
YANGs | Fluvial sediment transport model | Slingerland, Rudy |