August 5, 2022 Software Open Access

Personnettaz, Paolo; Weber, Norbert; Weier, Tom

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{
  "note": "This project has received funding from the European Union's Horizon 2020\nresearch and innovation programme under grant agreement No 963599, and was supported by\nthe Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) by award number\n338560565, by a postdoc fellowship of the German Academic Exchange Service (DAAD) and in\nframe of the Helmholtz\u2014RSF Joint Research Group \"Magnetohydrodynamic instabilities: Crucial\nrelevance for large scale liquid metal batteries and the sun-climate connection\", contract No. HRSF-\n0044 and RSF-18-41-06201. We thank P. Personnettaz for providing the source code and example.", 
  "version": "0.1.0", 
  "DOI": "10.14278/rodare.1828", 
  "issued": {
    "date-parts": [
      [
        2022, 
        8, 
        5
      ]
    ]
  }, 
  "title": "hmctFOAM - heat mass concentration transport FOAM", 
  "publisher": "Rodare", 
  "author": [
    {
      "family": "Personnettaz, Paolo"
    }, 
    {
      "family": "Weber, Norbert"
    }, 
    {
      "family": "Weier, Tom"
    }
  ], 
  "id": "1828", 
  "type": "article", 
  "language": "eng", 
  "abstract": "<p>This software illustrates the applications of the programming<br>\ntechniques detailed in the book chapter</p>\n\n<p>Norbert Weber, Tom Weier (2022) Liquid Metal Batteries. In: Steven<br>\nBeale, Werner Lehnert (eds.) Electrochemical Cell Calculations with<br>\nOpenFOAM. Lecture Notes in Energy 42, pp. 193-212.</p>\n\n<p>The included solver handles the heat and mass transport equations<br>\nunder the assumption of pure diffusion and with solutal convection.<br>\nIt is a single region solver that is based on laplacianFoam and<br>\nboussinesqPimpleFoam from OpenFOAM 6.</p>"
}