Identity and the natural environment: The psychological significance of nature LRW Clayton Mit Press, 2003 | 1041* | 2003 |

Scientific Computation P Joly, A Quarteroni, J Rappaz | 475 | 2006 |

Coupling fluid flow with porous media flow WJ Layton, F Schieweck, I Yotov SIAM Journal on Numerical Analysis 40 (6), 2195-2218, 2002 | 474 | 2002 |

Introduction to the numerical analysis of incompressible viscous flows W Layton Siam, 2008 | 242 | 2008 |

A Two-Level Method with Backtracking for the Navier--Stokes Equations W Layton, L Tobiska SIAM Journal on Numerical Analysis 35 (5), 2035-2054, 1998 | 185 | 1998 |

A two-level discretization method for the Navier-Stokes equations W Layton Computers & Mathematics with Applications 26 (2), 33-38, 1993 | 175 | 1993 |

A connection between subgrid scale eddy viscosity and mixed methods W Layton Applied Mathematics and Computation 133 (1), 147-157, 2002 | 144 | 2002 |

Approximation of the larger eddies in fluid motions II: A model for space-filtered flow GP GALDI, WJ LAYTON Mathematical Models and Methods in Applied Sciences 10 (03), 343-350, 2000 | 140 | 2000 |

A two-level variational multiscale method for convection-dominated convection–diffusion equations V John, S Kaya, W Layton Computer Methods in Applied Mechanics and Engineering 195 (33-36), 4594-4603, 2006 | 113 | 2006 |

Two-level Picard and modified Picard methods for the Navier-Stokes equations W Layton, W Lenferink Applied Mathematics and Computation 69 (2-3), 263-274, 1995 | 104 | 1995 |

On a well-posed turbulence model W Layton, R Lewandowski Discrete and continuous dynamical systems series B 6 (1), 111, 2006 | 103 | 2006 |

Approximate deconvolution models of turbulence: analysis, phenomenology and numerical analysis WJ Layton, LG Rebholz Springer Science & Business Media, 2012 | 101 | 2012 |

An analysis of the finite element method for natural convection problems J Boland, W Layton Numerical Methods for Partial Differential Equations 6 (2), 115-126, 1990 | 97 | 1990 |

A multilevel mesh independence principle for the Navier–Stokes equations W Layton, HWJ Lenferink SIAM Journal on Numerical Analysis 33 (1), 17-30, 1996 | 94 | 1996 |

A two-level method for the discretization of nonlinear boundary value problems O Axelsson, W Layton SIAM journal on numerical analysis 33 (6), 2359-2374, 1996 | 88 | 1996 |

On the accuracy of the rotation form in simulations of the Navier–Stokes equations W Layton, CC Manica, M Neda, M Olshanskii, LG Rebholz Journal of Computational Physics 228 (9), 3433-3447, 2009 | 84 | 2009 |

Error analysis for finite element methods for steady natural convection problems J Boland, W Layton Numerical functional analysis and optimization 11 (5-6), 449-483, 1990 | 84 | 1990 |

Numerical analysis and computational testing of a high accuracy Leray‐deconvolution model of turbulence W Layton, CC Manica, M Neda, LG Rebholz Numerical Methods for Partial Differential Equations: An International …, 2008 | 83 | 2008 |

A simple and stable scale-similarity model for large eddy simulation: energy balance and existence of weak solutions W Layton, R Lewandowski Applied mathematics letters 16 (8), 1205-1209, 2003 | 83 | 2003 |

A defect-correction method for the incompressible Navier–Stokes equations W Layton, HK Lee, J Peterson Applied Mathematics and Computation 129 (1), 1-19, 2002 | 81 | 2002 |