Does anyone know what kind of surface is defined by this equation? $$z=\left(x^2+y^2+z^2\right)^2$$
Thank you in advance.
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Not sure if it has a name.
Given fixed $z,$ then:
$$x^2+y^2=\sqrt{z}-z^2$$ So you need $0\leq z\leq 1$ for $x^2+y^2\geq 0.$ At $z=0$ and $z=1$ the set of solutions is the single point $(x,y)=(0,0).$ For any other $z$ in that range, the cross section curve is a circle.
Topologically, it is a sphere.
Its interior is convex. This is because the second derivative of $\sqrt z-z^2$ is negative.
For small $\epsilon>0$ the cross section at $z=1-\epsilon$ has radius approximately $\sqrt{3\epsilon/2},$ and the cross section at $z=\epsilon$ is of radius $\approx \sqrt[4]{z},$ because when $z=\epsilon$, $\sqrt z-z^2\approx \sqrt z.$
This means that the surface is flat at both ends, like a sphere of radius $\frac{3}4$ and center $(0,0,1/4)$ near $z=1$ and an even flatter side near $z=0.$
When $z=1/2$ the radius of the circle cross-section is at its largest, which is $\frac12\sqrt{2\sqrt 2-1}\approx 0.676.$
Thomas Andrews
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It seems that doesn't have a name, indeed. And I totally agree with your analysis, that $0\leq z \leq1$ limits the surface and the flatness regions. Thank you!! – fourier Jul 10 '21 at 22:14
$r = \sqrt[3]{\cos \theta}$.
I wasn't sure if there was a specific name, but that doesn't seem to be the case. Anyway, "dumpling" is an excellent name. It is baptized. (;
Thank you all.
– fourier Jul 10 '21 at 22:08