Construction of Scherk's surface using soap films

Question

I am currently interested in the differential geometry of minimal surfaces, and I have a rather trivial question regarding Scherk's surface (the one which can be parametrised by the real function $(x,y)\mapsto\ln\big(\frac{\cos(x)}{\cos(y)}\big)$).

On the internet, it appears that a fraction of this surface can be constructed/modelled with a cube in which some edges are removed, shrinking it into a soapy solution, as in the picture that I share with you just below.

However, how can one be completely certain that this really represents such a surface, and it is not just another surface that happens to look the same as Scherk's one?

I don't have enough bibliographical information to check whether someone already pointed out the link between the surface and such a model, so I would really appreciate some kind or reference so I can learn more about this, and other soap-film models.

Thank you in advance for your answers.

Answer 1

Your question is actually related to a somewhat non-trivial property of the minimal graph equation (and related non-linear elliptic equations) that goes back to work of Jenkins and Serrin.

The basic idea is that the Scherk solution should be an example of a larger class of solutions considered by Jenkins-Serrin

In their paper, polygons (with an even number of faces) in the plane are considered and a type of infinite boundary condition for the minimal graph equation is imposed. This consists of asking that the function become $+\infty$ and $-\infty$ on alternating faces of the polygon. Under appropriate conditions on the polygon such a solution is showed to exist and is unique in the class of graphical solutions. The Scherk solution you wrote down is the Jenkin-Serrin solution for the square $[-\frac{\pi}{2}, \frac{\pi}{2}]\times [-\frac{\pi}{2}, \frac{\pi}{2}]$.

This relates to your question as this solution is constructed as the limit of the solutions of the minimal graph equation, $u_N$, that have finite boundary $+N$ and $-N$ on alternating faces. Such solutions were shown to exist earlier by work of Nitsche.

The minimal surface in your picture should (for physical reasons mentioned already) be well approximated by one of the $u_N$ and so should approximately what the Scherk surface looks like (am not sure how high the $N$ has to be to give an approximation to desired accuracy, but imagine it can be estimated).