Welcome to the ParFlow User’s Manual
Reed M. Maxwell 1, Stefan J. Kollet 2, Laura E. Condon 3, Steven G. Smith 4, Carol S. Woodward 5, Robert D. Falgout 6, Ian M. Ferguson 7, Nicholas Engdahl 8, Jaro Hokkanen 9, George Artavanis 1, Benjamin West 3, Chen Yang 1, Basile Hector 10, James Gilbert 11, Lindsay Bearup 7, Jennifer Jefferson 12, Chuck Baldwin, William J. Bosl 13, Richard Hornung 4, Steven Ashby 14, Ketan B. Kulkarni 15
- 1. Introduction
- 2. Getting Started
- 3. The ParFlow System
- 4. Model Equations
- 5. ParFlow Files
- 5.1. Main Input Files (.tcl, .py, .ipynb)
- 5.2. ParFlow Binary Files (.pfb)
- 5.3. ParFlow CLM Single Output Binary Files (.c.pfb)
- 5.4. ParFlow Scattered Binary Files (.pfsb)
- 5.5. ParFlow Solid Files (.pfsol)
- 5.6. ParFlow Well Output File (.wells)
- 5.7. ParFlow Simple ASCII and Simple Binary Files (.sa and .sb)
- 6. ParFlow Input Keys
- 6.1. Input File Format Number
- 6.2. Computing Topology
- 6.3. Computational Grid
- 6.4. Geometries
- 6.5. Reservoirs
- 6.6. Timing Information
- 6.7. Time Cycles
- 6.8. Domain
- 6.9. Phases and Contaminants
- 6.10. Gravity, Phase Density and Phase Viscosity
- 6.11. Chemical Reactions
- 6.12. Permeability
- 6.13. Porosity
- 6.14. Specific Storage
- 6.15. dZMultipliers
- 6.16. Flow Barriers
- 6.17. Manning’s Roughness Values
- 6.18. Topographical Slopes
- 6.19. Retardation
- 6.20. Full Multiphase Mobilities
- 6.21. Richards’ Equation Relative Permeabilities
- 6.22. Phase Sources
- 6.23. Capillary Pressures
- 6.24. Saturation
- 6.25. Internal Boundary Conditions
- 6.26. Boundary Conditions: Pressure
- 6.27. Boundary Conditions: Saturation
- 6.28. Initial Conditions: Phase Saturations
- 6.29. Initial Conditions: Pressure
- 6.30. Initial Conditions: Phase Concentrations
- 6.31. Known Exact Solution
- 6.32. Wells
- 6.33. Code Parameters
- 6.34. SILO Options
- 6.35. Richards’ Equation Solver Parameters
- 6.36. Spinup Options
- 6.37. CLM Solver Parameters
- 6.38. ParFlow NetCDF4 Parallel I/O
- 6.39. NetCDF4 Chunking
- 6.40. NetCDF4 Compression
- 6.41. ROMIO Hints
- 6.42. Node Level Collective I/O
- 6.43. NetCDF4 Initial Conditions: Pressure
- 6.44. NetCDF4 Slopes
- 6.45. NetCDF4 Transient EvapTrans Forcing
- 6.46. NetCDF4 CLM Output
- 6.47. NetCDF4 CLM Input/Forcing
- 6.48. NetCDF Testing Little Washita Test Case
- 7. Manipulating Data: PFTools
- 8. Python
- 9. Bibliography
- 1(1,2,3)
Department of Civil and Environmental Engineering, The High Meadows Environmental Institute, and the Integrated GroundWater Modeling Center, Princeton University, Princeton, NJ, USA. reedmaxwell@princeton.edu
- 2
Institute for Bio- and Geosciences, Agrosphere (IBG-3) and Centre for High-Performance Scientific Computing in Terrestrial Systems, Research Centre Jülich, Jülich, Germany. s.kollet@fz-juelich.de
- 3(1,2)
Department of Hydrology and Atmospheric Sciences, University of Arizona, Tucson, USA. lecondon@arizona.edu
- 4(1,2)
Center for Applied Scientific Computing, Lawrence Livermore National Laboratory, Livermore, CA. USA.
- 5
Center for Applied Scientific Computing, Lawrence Livermore National Laboratory, Livermore, CA, USA. cswoodward@llnl.gov
- 6
Center for Applied Scientific Computing, Lawrence Livermore National Laboratory, Livermore, CA, USA.
- 7(1,2)
US Bureau of Reclamation, Denver, CO, USA.
- 8
Civil and Environmental Engineering, Washington State University, Pullman, WA, USA. nick.engdahl@wsu.edu
- 9
CSC - IT Center for Science, Espoo, Finland
- 10
Université Grenoble-Alpes/IRD/IGE, Grenoble, FR.
- 11
University of California, Santa Cruz & NOAA Fisheries Southwest Fisheries Science Center, Santa Cruz, CA, USA
- 12
HNTB, Milwaukee, Wisconsin, United States.
- 13
Children’s Hospital Informatics Program, Harvard Medical School, Boston, MA, USA.
- 14
Pacific Northwest National Laboratory, Richland, WA, USA.
- 15
Jülich Supercomputing Centre and Centre for High-Performance Scientific Computing in Terrestrial Systems, Research Centre Jülich, Jülich, Germany.