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Relativity forbids the existence of perfectly rigid bodies (https://einstein.stanford.edu/content/relativity/q2018.html), because that would imply that the speed of sound would be infinite in such a body in contradiction to relativity. This also means that the incompressible Navier Stokes equations violate relativity and are only useful as an approximation to real flows.

Why is it then that mathematicans care so much about solutions to these equations (https://en.wikipedia.org/wiki/Navier%E2%80%93Stokes_existence_and_smoothness) if we already know from physics, that these equations must be inconsistent with the real world? Why don't they care more about the compressible Navier-Stokes equations?

Update: Maybe my intention with the question was unclear. I wonder why the mathematicians working on the incompressible Navier-Stokes equations don't take the physics of the equations more into account? Could it not be that the physics behind the equations might help to find insights into the solution space of these equations?

asmaier
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    Because the incompressible equations are a mathematically nicer model that we still don't really understand. – Ben Grossmann Nov 08 '15 at 18:50
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    Finding a solution of some mathematics problem can be mathematically interesting without even thinking about does it have applications in other fields? – Farewell Nov 08 '15 at 18:51
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    do mathematicians really care about this? – James S. Cook Nov 08 '15 at 18:56
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    Should we not "care" about ballistic trajectories or the ratio of circles' circumference to diameter because the equations are inconsistent with the real world at relativistic scales? – hardmath Nov 08 '15 at 18:58
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    Relativistic contraints are essentially irrelevant for any sensible application of PDEs to anything. – Mariano Suárez-Álvarez Nov 09 '15 at 06:21
  • More evidence that the Navier-Stokes equations are incomplete: https://www.quantamagazine.org/20150721-famous-fluid-equations-are-incomplete/ – asmaier Jun 11 '16 at 16:44
  • @asmaier Even for the incompressible N-S, if I correctly recall, several works go on to assume that the Reynold's number is around 10, or at least small. For instance, $\mathrm{Re} \simeq \mathcal{O}(\text{million})$ for aerodynamic flows over aircraft wings. So the incompressibility assumption is not the one you should worry about when thinking about practical applications. They study these equations for their mathematical properties. – ares Apr 24 '19 at 02:31

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Two different answers:

First, it is an interesting mathematical problem unto itself. The mathematics community cares a lot about problems that are really not applicable to the real world.

Second, in applied mathematics we spend a lot of time looking at extreme limits. For example, in statistical mechanics, we frequently consider the "thermodynamic limit", wherein we work with an arbitrarily large number of particles and appropriately scale the other variables (for instance volume) to get the right behavior when we take the limit of infinitely many particles. In reality there are no systems with infinitely many particles, but at the same time this approximation is extremely accurate because our ordinary macroscopic objects are comprised of so many small components.

Using Navier-Stokes in the first place is very similar to this thermodynamic limit: real fluids are made of atoms, not continuum material, but there are so many atoms that thinking of them as continuous is usually accurate and makes the problem much more tractable.

The use of the incompressibility approximation in the Navier-Stokes equations is similar: real fluids are all compressible, but the compressibility of many important fluids, like water under typical conditions, is so astonishingly small that the incompressible approximation is reasonable, provided the external force is not too huge and neither the compressible solution nor the incompressible solution has any singularities.

Ian
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To someone who likes pure mathematics, in a sense that he does not need that the solutions of certain mathematical problems have practical applications in other fields, a problem like Navier-Stokes problem could be interesting in itself as some kind of gem inside the field of partial differential equations.

Although some problems inside mathematics were formulated with the motivation that was somehow based on the practical aspects they still can be viewed as problems which reside inside certain mathematical field, and they are worth something even if they do not have practical applications at all.

This maybe could have been a few comments but as I think that is better that as many questions as possible have an answer I wrote this as an answer.

Edit after your update: Is it realistic to expect that if the incompressible case is not solved that compressible case could be solved before if compressible case looks more complex than incompressible? Although both cases are approximations it is somehow natural to try to prove first the easier case and then go into more generality, but if you think that there is some way that could first settle the case that looks harder and more complex, in which density is not constant, then I wish you luck.

Farewell
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Because of its very fundamental importance in Fluid dynamics applications, is again involving complex analysis and pdes. (CR relations, Zhoukowski airfoil, Von Karman Vortex formation).

Clay institute reward ( once an incorrect solution was submitted and withdrawn, iirc).

Narasimham
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