Difference between revisions of "Main Page"
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<big>'''Features'''</big> | <big>'''Features'''</big> | ||
| − | NekCEM is a high-fidelity electromagnetic solver that has been developed at Mathematics and Computer Science Division of Argonne National Laboratory. It's an open source code | + | NekCEM is a high-fidelity electromagnetic solver that has been developed at Mathematics and Computer Science Division of Argonne National Laboratory. It's an open source code, written by Misun Min, Jing Fu, Andreas Kloeckner in 1996-2011, with technical input from P. Fischer [http://www.mcs.anl.gov/~fischer] provided with the core structure of the incompressible Navier-Stokes solver Nek5000[http://nek5000.mcs.anl.gov]. |
| − | + | The code is written in Fortran and C, using MPI for parallel communication. | |
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The code targets predicting optimal designs of next-generation electromagnetic | The code targets predicting optimal designs of next-generation electromagnetic | ||
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* Light transmission calculations for nanodevices | * Light transmission calculations for nanodevices | ||
* Wakepotential calculations for accelerator devices | * Wakepotential calculations for accelerator devices | ||
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| + | <big>'''Upcoming'''</big> | ||
<big>'''Instruction'''</big> | <big>'''Instruction'''</big> | ||
Revision as of 13:32, 12 June 2011
Features
NekCEM is a high-fidelity electromagnetic solver that has been developed at Mathematics and Computer Science Division of Argonne National Laboratory. It's an open source code, written by Misun Min, Jing Fu, Andreas Kloeckner in 1996-2011, with technical input from P. Fischer [1] provided with the core structure of the incompressible Navier-Stokes solver Nek5000[2]. The code is written in Fortran and C, using MPI for parallel communication.
The code targets predicting optimal designs of next-generation electromagnetic devices such as accelerator components for the International Linear Collider or the Large Hadron Collider, nanosensors for molecular detection, and photovoltaic solar cells with high energy-conversion efficiency to run on advanced computer architectures.
- High-order spectral element discretizations
- Hexahedral boody conforming meshes
- The 4th-order Runge-Kutta timestepping
- The high-order exponential time integration
- Light transmission calculations for nanodevices
- Wakepotential calculations for accelerator devices
Upcoming
Instruction
- Documentation for data file setting
- Documentation for parallel I/O option
- Documentation for restart option
- Documentation for how to compile/run
Current Developers
Getting started
Consult the User's Guide for information on using the wiki software.
