Difference between revisions of "Main Page"

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* Lattice Boltzmann approach for collision step
 
* Lattice Boltzmann approach for collision step
 
* Spectral element discontinuous Galerkin discretization for advection step
 
* Spectral element discontinuous Galerkin discretization for advection step
* Advection-diffusion solver for heat transfer
+
* Advection-diffusion equation solver for heat transfer
 
* Hexahedral body conforming meshes
 
* Hexahedral body conforming meshes
 
* The 4th-order Runge-Kutta timestepping  
 
* The 4th-order Runge-Kutta timestepping  
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* Flows past a cylinder and cylinders in tandum
 
* Flows past a cylinder and cylinders in tandum
 
* Flows past a hemisphere
 
* Flows past a hemisphere
* Turbulent channel flows
+
* Turbulent flows in a channel
* Natural convections in a square and an annulus
+
* Natural convection flows in a square and an annulus
 
* high parallel efficiency scaling over 100,000 cores  
 
* high parallel efficiency scaling over 100,000 cores  
 
* parallel IO scaling over 65,000 cores  
 
* parallel IO scaling over 65,000 cores  

Revision as of 13:50, 28 August 2013

Welcome to NekLBM

NekLBM https://svn.mcs.anl.gov/repos/NEKLBM is a high-order lattice Boltzmann fluid solver based on spectral element discontinuous Galerkin methods. It is an open-source code written in Fortran and C. The code is actively developed at Mathematics and Computer Science Division of Argonne National Laboratory.

Current Developers

Misun Min [1], Taehun Lee [2], Saumil Patel, Kalu Uga

Features

  • Lattice Boltzmann approach for collision step
  • Spectral element discontinuous Galerkin discretization for advection step
  • Advection-diffusion equation solver for heat transfer
  • Hexahedral body conforming meshes
  • The 4th-order Runge-Kutta timestepping
  • The high-order exponential time integration
  • Flows past a cylinder and cylinders in tandum
  • Flows past a hemisphere
  • Turbulent flows in a channel
  • Natural convection flows in a square and an annulus
  • high parallel efficiency scaling over 100,000 cores
  • parallel IO scaling over 65,000 cores



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