Teaching and Learning of Fluid Mechanics

doi:10.3390/books978-3-03936-444-2

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Teaching and Learning of Fluid Mechanics

Edited by

July 2020

362 pages

ISBN978-3-03936-443-5 (Hardback)
ISBN978-3-03936-444-2 (PDF)

https://doi.org/10.3390/books978-3-03936-444-2

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This book is a reprint of the Special Issue Teaching and Learning of Fluid Mechanics that was published in

Engineering

Physical Sciences

Summary

This book contains research on the pedagogical aspects of fluid mechanics and includes case studies, lesson plans, articles on historical aspects of fluid mechanics, and novel and interesting experiments and theoretical calculations that convey complex ideas in creative ways. The current volume showcases the teaching practices of fluid dynamicists from different disciplines, ranging from mathematics, physics, mechanical engineering, and environmental engineering to chemical engineering. The suitability of these articles ranges from early undergraduate to graduate level courses and can be read by faculty and students alike. We hope this collection will encourage cross-disciplinary pedagogical practices and give students a glimpse of the wide range of applications of fluid dynamics.

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Hardback

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Keywords

undergraduate education; fluid mechanics; pipeline flow; non-equilibrium thermodynamics; entropy generation; pressure loss; experimental studies; Colebrook equation; Lambert W function; Padé polynomials; iterative methods; explicit approximations; learning; teaching strategies; floating-point computations; undergraduate education; applications of fluids; fluid mechanics; packed bed; porous media; non-equilibrium thermodynamics; entropy generation; pressure loss; Ergun equation; Forchheimer equation; CFD; Julia; numerical analysis; finite difference; spectral methods; multigrid; computational fluid dynamics; finite-volume method; discretization; turbulence modelling; meshing; Pan’s flute; music; sound frequencies; wind instruments; multiphase flow; slugging; flooding; bottle; bubbles; teaching and learning fluids; teaching and learning pressure; alternative conceptions; teaching learning sequences; conceptual change; constructivism; fluid mechanics; science teaching; hands-on/minds-on/hearts-on; inquiry-based problem; science learning; educational activities; FMCI; Strasbourg University; fluid mechanics; Legitimation Code Theory; undergraduate teaching; fluid mechanics; permeability; finite element method; homogenization; microstructure; micro-CT; laboratory demonstration; physical modelling; flood risk assessment; sediment transport; infrastructure scour hazards; outreach; water engineering; fluid dynamics education; applied mathematics education; computational fluid dynamics; fluids visualization; open-source CFD; projection method; spectral fluid solver; Lattice Boltzmann Method; cavity flow; circular flow; interacting vortices; flow past cylinder; flow past porous cylinder; MATLAB; Python; Langevin; Fokker–Planck; microrheology; Stokes–Einstein relation; mobility; fluctuation dissipation; Matlab GUI; n/a