MurfMd

A Multidimension, Multiregion Finite Element Subsurface Flow Model for Slightly Compressible, Variably Saturated Structured Subsurface Media

User's Manual

Y12 MurfMd Model - Working Log

Introduction

The computer code MurfMd was originally developed by J. P. (Jack) Gwo and G.-T. (George) Yeh at the Pennsylvania Sate University. It is a multi-dimensional version of the original MURF model (Gwo et al., 1994b). On the basis of the multiregion flow theory in subsurface media developed by Gwo et al. (1996), we present here a multidimension, multiregion finite element subsurface flow model MurfMd. The governing equations for the model and the various boundary conditions incorporated in the model are described in Gwo et al. (1994b). The numerical implementation of MURF, using a Galerkin finite element method, is briefly discussed in the report. The mass transfer process in the model is assumed linear and steady. In addition to its multi-dimensional implementation, MurfMd also accommodates various one-dimensional and three-dimensional elements such as line elements, tetrahedrons, pentahedrons, and hexahedrons.

MurfMd has been tested on various Unix workstations and PC platforms. Applications of MurfMd to various subsurface flow and contaminant transport problems may be found in the literature (e.g., Gwo et al., 1994a, 1994b, 1995, 1996, 1998, 1999; Wilson et al., 1994, 1998). OpenMP parallel directives are also implemented for parallel, high performance platforms such as IBM SP, Cray PVPs, and so on. Executable binaries on PCs and a number of Unix workstations will be made available in the near future. The input data guide is available online. For a hard copy of the MURF report (Gwo et al., 1994), please contact Dr. J. P. Gwo. Comments and bug reports are very much appreciated and should be directed to J. P. Gwo.

License

This software was produced under U.S. Government contract (DE-AC05-00OR22725) by the Oak Ridge National Laboratory, which is managed by UT-Battelle, LLC, for the U.S. Department of Energy. This software (including any documentation) is a public-domain research code. You have the non-exclusive right to use this software free of charge. You have the right to make modifications to the source code for your own use. This software has not yet been evaluated and cleared for commercialization. This software (or parts of it) is not intended for duplication or distribution to third parties without the permission of UT-Battelle, LLC.

Disclaimer

The user of this software codes, there sources and documentations accepts and uses it at his or her own risk. The authors do not make any expressed or implied warranty of any kind with regard to this software. Nor shall the authors be liable for incidental or consequential damages with or arising out of the furnishing, use, or performance of this software.

DISCLAIMER OF LIABILITY: Documents available from this server were prepared as an account of work sponsored by an agency of the U.S. Government. Neither the U.S. Government nor any agency thereof, or any of their employees, or the author, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights.

DISCLAIMER OF ENDORSEMENT: Reference to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the U.S. Government or any agency thereof. The views and opinions of document authors do not necessarily state or reflect those of the U.S. Government or any agency thereof.

COPYRIGHT STATUS: Documents provided from this server were previously sponsored by a contractor of the U.S. Government Accordingly, the U.S. Government retains a nonexclusive, royalty-free license to publish or reproduce these documents, or to allow others to do so, for U.S. Government purposes.

WARNING: Any unauthorized access to this system is prohibited and is subject to criminal and civil penalties under Federal Laws (including but not limited to Public Laws 83-703 and 99-474). Individuals using this system are subject to having all activities on this system monitored by system or security personnel. Anyone using this system expressly consents to such monitoring.

User Data Input Guide Seventeen data sets are required to complete a user input data file, as follows:

1. title.
2. Integer parameters.
3. Real parameters.
4. Printout control.
5. Material property.
6. Soil property.
7. Nodal coordinate.
8. Element connectivity.
9. Material type change.
10. Initial condition.
11. Boundary dimension and control.
12. Source and sink.
13. Varaible boundary (rainfall, evaporation, seepage, river).
14. Dirichlet boundary.
15. Cauchy boundary.
16. Neumann boundary.
17. End of Job.

Executable Binaries: MS Windows

I have read the Legal Notice and License above and agree to the terms described therein. yes no

Intel/Microsoft Windows 2000
Post-Processing Utility

Example Input Files

Example of input superfile
Example input files

ORNL WAG 5
Two-dimensional Drainage
Three-dimensional Pumping Well

References

Gwo, J. P., P. M. Jardine, G. V. Wilson, and G. T. Yeh. 1994a. Modeling small-scale physical non-equilibrium and large-scale preferential fluid and solute transport in a structured soil. In A. Peters, G. Wittum, B. Herrling, U. Meissner, C. A. Brebbia, W. G. Gray, and G. F. Pinder (eds.), Computational Methods in Water Resources X. p.465-472.

Gwo, J. P., P. M. Jardine, G. T. Yeh, and G. V. Wilson. 1994b. MURF User's Guide: A Finite Element Model of Multiple-Pore-Region Flow Through Variably Saturated Subsurface Media. ORNL/GWPO-011, Oak Ridge National Laboratory.

Wilson, G. V., P. M. Jardine, R. J. Luxmoore, and J. P. Gwo, Multi-region flow and transport in unsaturated soil. (In) S. G. Pandalai (ed.), Trends in Hydrology. Council of Scientific Information. Trvivandrum, India. p.279-290. 1994.

Gwo, J. P., P. M. Jardine, G. V. Wilson, and G. T. Yeh. 1995. A multiple-pore-region concept to modeling mass transfer in subsurface media. J. Hydrol. 164: 217-237.

Gwo, J. P., P. M. Jardine, G. V. Wilson, and G. T. Yeh. 1996. Using a multiregion model to study the effects of advective and diffusive mass transfer on local physical nonequilibrium and solute mobility in a structured soil. Water Resour. Res. 32: 561-570.

Gwo, J. P., R. O'Brien, and P. M. Jardine. 1998. Mass transfer in structured porous media: Embedding mesoscale structure and microscale hydrodynamics in a two-region model. J. Hydrol. 208: 204-222.

Wilson, G.V., J.P. Gwo, P.M. Jardine, and R.J. Luxmoore. 1998. Hydraulic and Physical Nonequilibrium Effects on Multiregion Flow and Transport. In H.M. Selim and L. Ma (eds.), Physical Nonequilibrium in Soils: Modeling and Application, p.37-61, Ann Arbor Press, Inc., Michigan.

Gwo, J. P., G. V. Wilson, P. M. Jardine, and E. F. D'Azevedo, 1999. Modeling subsurface contaminant reactions and transport at the watershed scale. In Corwin, D. L., K. Loague, and T. R. Ellsworth (eds.) Assessment of Non-Point Source Pollution in the Vadose Zone, American Geophysical Union, Washington D. C., p31-43.

This homepage is maintained by J.P. Jack Gwo. Last updated: 11/12/2008.