His primary scientific interests are in Mechanics, Finite element method, Flow, Computer simulation and Constitutive equation. His studies deal with areas such as Discretization, Die swell and Numerical analysis as well as Mechanics. His work deals with themes such as Simple shear, Numerical integration, Vortex, Deborah number and Glass fiber, which intersect with Finite element method.
His study in Vortex is interdisciplinary in nature, drawing from both Viscoelastic fluid and Upper-convected Maxwell model. His work is dedicated to discovering how Flow, Viscoelasticity are connected with Advection, Stress and Upwind scheme and other disciplines. His studies in Constitutive equation integrate themes in fields like Continuum mechanics and Classical mechanics.
Mechanics, Finite element method, Viscoelasticity, Flow and Computer simulation are his primary areas of study. His Mechanics research includes themes of Classical mechanics and Constitutive equation. The concepts of his Finite element method study are interwoven with issues in Streamlines, streaklines, and pathlines, Stokes flow and Mathematical analysis, Boundary value problem.
His Viscoelasticity study combines topics in areas such as Upwind scheme, Galerkin method, Stress, Inertia and Drag. As a part of the same scientific study, Marcel Crochet usually deals with the Flow, concentrating on Numerical analysis and frequently concerns with Capillary action. His Computer simulation study deals with Two-dimensional flow intersecting with Simulation.
Marcel Crochet mainly focuses on Mechanics, Computer simulation, Finite element method, Viscoelasticity and Flow. His Mechanics study frequently involves adjacent topics like Die swell. His research integrates issues of Shear flow, Rheology, Contraction ratio and Constitutive equation in his study of Computer simulation.
Marcel Crochet frequently studies issues relating to Connection and Finite element method. His Viscoelasticity research incorporates themes from Vortex, Polymer and Newtonian fluid. The various areas that he examines in his Flow study include Upwind scheme, Kinematics, Mathematical analysis and Rotational symmetry.
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Numerical Simulation of Non-Newtonian Flow
M. J. Crochet;A. R. Davies;K. Walters;R. I. Tanner.
A new mixed finite element for calculating viscoelastic flow
Jm. Marchal;Marcel Crochet.
Journal of Non-newtonian Fluid Mechanics (1987)
Direct simulation of fluid particle motions
Howard H. Hu;Daniel D. Joseph;Marcel J. Crochet.
Theoretical and Computational Fluid Dynamics (1992)
Global modelling of heat transfer in crystal growth furnaces
François Dupret;P. Nicodeme;Y. Ryckmans;Pascale Wouters.
International Journal of Heat and Mass Transfer (1990)
Finite-element Analysis of Die Swell of a Highly Elastic Fluid
Marcel Crochet;Roland Keunings.
Journal of Non-newtonian Fluid Mechanics (1982)
Die Swell of a Maxwell Fluid - Numerical Prediction
Marcel Crochet;Roland Keunings.
Journal of Non-newtonian Fluid Mechanics (1980)
Numerical Prediction of Fiber Orientation in Dilute Suspensions
Rc. Givler;Marcel Crochet;Rb. Pipes.
Journal of Composite Materials (1983)
Ionospheric modification experiments in northern Scandinavia
P. Stubbe;H. Kopka;H. Lauche;M. T. Rietveld.
web science (1982)
ON CONSTITUTIVE EQUATIONS FOR FLOW OF FLUID THROUGH AN ELASTIC SOLID.
M.J. Crochet;P.M. Naghdi.
International Journal of Engineering Science (1966)
Numerical Methods in Non-Newtonian Fluid Mechanics
Marcel Crochet;K. Walters.
Annual Review of Fluid Mechanics (1983)
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