A vivid introduction to fluid simulation.

Topics covered: rarefied gas dynamics, continuum gas dynamics, fluid motion descriptions & coordinates (spatially fixed (Eulerian), materialfixed (Lagrangian), arbitrary), reducibility aspects, motivation on modeling unresolved flow structures, ensemble averages of microscopically and macroscopically varying data, usefulness of the modeling hierarchy, simplifying and decoupling the evolution equations, NavierStokes equations, compressible flow and the incompressible flow assumptions, and buoyancydriven flow (Boussinesq approximation).


Special thanks to my supporters:

AxisAngles
Yuxuan Zhang
Houston Lucas
Patrick Gibson
... and all my patrons!

If you like what you see and want to support my work, join my Patreon feed. I really appreciate it!
  / braintruffle  


Timetable:

00:00 What's going on
02:15 Recap on continuous fluid fields
05:06 Continuous evolution and local similarity
06:52 Motion description and evolution equations
20:41 Ensemble averages of macroscopic data
23:52 Usefulness of the modeling hierarchy
25:13 Playing with the equations
27:50 Compressible and incompressible flow
32:39 Buoyancydriven flow
37:22 Decoupling of the equations
39:30 Thanks to my supporters and recap


Selected Learning Resources:

02:15 Continuous flow fields from rarefied gas dynamics and continuum gas dynamics: [1,2,3,4,5,6]
04:10 Continuous perspective on the microscale; continuum micromechanics (to be discussed): [7]
06:52 Fluid motion description and coordinates (spatially fixed (Eulerian), materialfixed (Lagrangian), arbitrary); evolution equations; material derivative; discretization aspects: [8,9,10]
22:05 Ensemble averages of microscopic and macroscopic data; modeling unresolved flow structures; Kolmogorov microscales (to be discussed); turbulence modelling (to be discussed); 2d vs 3d turbulence (to be discussed): [1,11,12]
27:50 Compressible flow; incompressible flow assumptions: [2]
32:39 Buoyancydriven flow (Boussinesq approximation); treating slight density variations: [13]
37:22 Decoupling the equations: [2]

References:
[1] Lecture Notes: from "http://volkov.eng.ua.edu/ME591_491_NE..." to "NEGD06"
[2] Book: White, Frank M. "Fluid mechanics." Tata McGrawHill Education, 2010.
[3] Book: Anderson, John D. "Governing equations of fluid dynamics. Computational fluid dynamics." Springer, Berlin, Heidelberg, 1992. 1551.
[4] Paper: Macrossan, M. N. "Scaling parameters for hypersonic flow: correlation of sphere drag data.", 2007.
[5] Lecture Notes: Cerfon, Antoine. "Mechanics (Classical and Quantum)." "https://www.math.nyu.edu/~cerfon/mech..."
[6] Lecture Notes: Kenkre, V. M.. "Statistical Mechanics." "https://www.unm.edu/~aierides/505/" specifically ".../bbgky2.pdf" & ".../bbgky3.pdf"
[7] Paper: Zaoui, André. "Continuum micromechanics: survey." Journal of Engineering MechanicsASCE 128.8 (2002): 808816.
[8] Essay: Price, James F. "Lagrangian and eulerian representations of fluid flow: Kinematics and the equations of motion." MIT OpenCourseWare, 2006.
[9] Book: Donea, J., Huerta, A., Ponthot, J.Ph. and RodríguezFerran, A., "Arbitrary LagrangianEulerian methods,
The Encyclopedia of Computational Mechanics", Wiley, Vol. 1, Chapter 14, pp. 413437, 2004
[10] Book: Bennett, Andrew. "Lagrangian fluid dynamics." Cambridge University Press, 2006.
[11] Lecture Notes: Lermusiaux, P. "Numerical Fluid Mechanics." "https://ocw.mit.edu/courses/229nume..."
[12] Paper: Boffetta, Guido, and Robert E. Ecke. "Twodimensional turbulence." Annual review of fluid mechanics 44.1 (2012): 427451.
[13] Paper: Mayeli, Peyman, and Gregory J. Sheard. "Buoyancydriven flows beyond the Boussinesq approximation: A brief review." International Communications in Heat and Mass Transfer 125 (2021): 105316.


Please note:

This series focuses specifically on the aspect of information reduction in dynamical systems. For clarity, I had to omit many exciting facets of the topics addressed in the video. So, the video itself is a reduction. :)

I hope you enjoyed this little braintruffle!