Spread of excitation in 3-D models of the anisotropic cardiac tissue. II. Effects of fiber architecture and ventricular geometry PC Franzone, L Guerri, M Pennacchio, B Taccardi Mathematical biosciences 147 (2), 131-171, 1998 | 151 | 1998 |

Multiscale modeling for the bioelectric activity of the heart M Pennacchio, G Savaré, PC Franzone SIAM Journal on Mathematical Analysis 37 (4), 1333-1370, 2005 | 144 | 2005 |

Efficient algebraic solution of reaction–diffusion systems for the cardiac excitation process M Pennacchio, V Simoncini Journal of Computational and Applied Mathematics 145 (1), 49-70, 2002 | 93 | 2002 |

Spread of excitation in 3-D models of the anisotropic cardiac tissue. III. Effects of ventricular geometry and fiber structure on the potential distribution PC Franzone, L Guerri, M Pennacchio, B Taccardi Mathematical biosciences 151 (1), 51-98, 1998 | 77 | 1998 |

Algebraic multigrid preconditioners for the bidomain reaction–diffusion system M Pennacchio, V Simoncini Applied numerical mathematics 59 (12), 3033-3050, 2009 | 66 | 2009 |

The mortar finite element method for the cardiac “bidomain” model of extracellular potential M Pennacchio Journal of Scientific Computing 20 (2), 191-210, 2004 | 47 | 2004 |

Anisotropic mechanisms for multiphasic unipolar electrograms: simulation studies and experimental recordings PC Franzone, L Guerri, M Pennacchio, B Taccardi Annals of biomedical engineering 28 (11), 1326-1342, 2000 | 44 | 2000 |

Fast structured AMG preconditioning for the bidomain model in electrocardiology M Pennacchio, V Simoncini SIAM Journal on Scientific Computing 33 (2), 721-745, 2011 | 34 | 2011 |

Accurate computation of electrograms in the left ventricular wall P Colli-Franzone, M Pennacchio, L Guerri Mathematical Models and Methods in Applied Sciences 10 (04), 507-538, 2000 | 26 | 2000 |

Substructuring preconditioners for mortar discretization of a degenerate evolution problem M Pennacchio, V Simoncini Journal of Scientific Computing 36 (3), 391-419, 2008 | 22 | 2008 |

BDDC and FETI-DP for the virtual element method S Bertoluzza, M Pennacchio, D Prada Calcolo 54 (4), 1565-1593, 2017 | 21 | 2017 |

Substructuring preconditioners for an $$$$-$$ p $$ p domain decomposition metod wit interior penalty mortaring PF Antonietti, BA De Dios, S Bertoluzza, M Pennacchio Calcolo 52 (3), 289-316, 2015 | 20* | 2015 |

A non-conforming domain decomposition method for the cardiac potential problem M Pennacchio Computers in Cardiology 2001. Vol. 28 (Cat. No. 01CH37287), 537-540, 2001 | 18 | 2001 |

Analysis of substructuring preconditioners for mortar methods in an abstract framework S Bertoluzza, M Pennacchio Applied mathematics letters 20 (2), 131-137, 2007 | 13 | 2007 |

Preconditioning the Mortar Method by Substructuring: The High Order Case. S Bertoluzza, M Pennacchio Applied Numerical Analysis & Computational Mathematics 1 (2), 434-454, 2004 | 12 | 2004 |

Solution of linear systems from an optimal control problem arising in wind simulation M Benzi, L Ferragut, M Pennacchio, V Simoncini Numerical Linear Algebra with Applications 17 (6), 895-915, 2010 | 11 | 2010 |

Non-symmetric algebraic multigrid preconditioners for the bidomain reaction–diffusion system M Pennacchio, V Simoncini Numerical Mathematics and Advanced Applications 2009, 729-736, 2010 | 6 | 2010 |

High order VEM on curved domains S Bertoluzza, M Pennacchio, D Prada arXiv preprint arXiv:1811.04755, 2018 | 5 | 2018 |

A Parallel Implementation of the Mortar Element Method in 2D and 3D A Samake, S Bertoluzza, M Pennacchio, C Prud'Homme, C Zaza | 5 | 2013 |

Substructuring preconditioners for parabolic problems by the mortar method M Pennacchio Int. J. Numer. Anal. Model., 5 (4), 527-542, 2008 | 4 | 2008 |