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Introduction to CFD Basics by Rajesh Bhaskaran & Lance Collins

Lectures in Computational Fluid Dynamics of Incompressible Flow by J. M. McDonough, Departments of Mechanical Engineering and Mathematics University of Kentucky

Solution Methods In Computational Fluid Dynamics by T. H. Pulliam, NASA

Fundamentals of Computational Fluid Dynamics by Harvard Lomax & Thomas H. Pulliam, NASA

Computational Fluid Dynamics by R. Verfurth, Ruhr-Universitat Bochum



Fluid mechanics, turbulent flow and turbulence modeling by Lars Davidson, Division of Fluid Dynamics Department of Applied Mechanics Chalmers University of Technology

Turbulence Modeling for Beginners by Tony Saad, University of Tennesse Space Institute



A Practical Introduction to the Lattice Boltzmann Method by Alexander J. Wagner, Department of Physics North Dakota State University

Lattice Boltzmann methods for multiphase flow and phase change heat transfer by Q. Li, K. H. Luo, Q. J. Kang, Y. L. He, Q. Chen & Q. Liu


Introduction to the Finite Volumes Method, Application to the Shallow Water Equations by Jaime Miguel Fe Marques

Introductory Finite Volume Methods for PDEs by D.M. Causon, C.G. Mingham & L. Qian

Finite Volume Methods by Robert Eymard, Thierry Gallouet & Raphaele Herbin

Finite Volume and Finite Element Methods in CFD by M. Feistauer, Charles University Prague, Faculty of Mathematics and Physics

Numerical Methods for Incompressible Flow by Martin Burger

Numerical Methods for Incompressible Viscous Flow by Hans Petter Langtangen, Kent-Andre Mardal, Dept. of Scientific Computing, Simula Research Laboratory and Dept. of Informatics, University of Oslo



Lecture Notes on Delaunay Mesh Generation by Jonathan Richard Shewchuk

Geometry and Topology of Mesh Generation by Herbert Edelsbrunner, Department of Computer Science, Duke University



Finite Element Methods for the Incompressible Navier-Stokes Equations by Rolf Rannacher, Institute of Applied Mathematics, University of Heidelberg

An Introduction to the Navier-Stokes Initial-Boundary Value Problem by Giovanni P. Galdi, Department of Mechanical Engineering, University of Pittsburgh



Wall y+ Strategy for Dealing with Wall-bounded Turbulent Flows by Salim .M. Salim, and S.C. Cheah,  International MultiConference of Engineers and Computer Scientists 2009 Vol II IMECS 2009, March 18 – 20, 2009, Hong Kong

The Influence of y+ in Wall Functions Applied in Ship Viscous Flows by S. ten Pas, BSc, MARIN (Maritime Research Institute Netherlands)

Near-wall grid adaptation for wall-functions by Th. Alrutz, T. Knopp, Institute of Aerodynamics and Flow Technology

Three-zonal Wall Function for k-ε Turbulence Models by M. Chmielewski, M. Gieras, Warsaw University of Technology, Institute of Heat Engineering

Near-wall behavior of RANS turbulence models and implications for wall functions by Georgi Kalitzin *, Gorazd Medic, Gianluca Iaccarino, Paul Durbin, Flow Physics and Computation Division, Department of Mechanical Engineering, Stanford University, Stanford