Reuleaux tetrahedron

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Animation of a Reuleaux tetrahedron, showing also the tetrahedron from which it is formed.

Four spheres intersect to form a Reuleaux tetrahedron.

The Reuleaux tetrahedron is the intersection of four spheres of radius s centered at the vertices of a regular tetrahedron with side length s. The sphere through each vertex passes through the other three vertices, which also form vertices of the Reuleaux tetrahedron. The Reuleaux tetrahedron has the same face structure as a regular tetrahedron, but with curved faces: four vertices, and four curved faces, connected by six circular-arc edges.

This shape is defined and named by analogy to the Reuleaux triangle, a two-dimensional shape with constant width. One can find repeated claims in the mathematical literature that the Reuleaux tetrahedron also has constant width, but it is not true: the two midpoints of opposite edge arcs are separated by a larger distance,

$(\sqrt3 - \sqrt2/2)s\approx 1.0249s.$

The volume of a Reuleaux tetrahedron is

$\frac{s^3}{12}(3\sqrt2 - 49\pi + 162\tan^{-1}\sqrt2)\approx 0.422s^3$

(Weisstein).

Meissner and Schiller (1912) showed how to modify the Reuleaux tetrahedron to form a shape of constant width, by replacing three of its edge arcs by curved patches formed as the surfaces of rotation of a circular arc. According to which three edge arcs are replaced (three that have a common vertex or three that form a triangle) there result two noncongruent shapes that are sometimes called Meissner bodies or Meissner tetrahedra. Bonnesen and Fenchel (1934) conjectured that Meissner tetrahedra are the minimum-volume three-dimensional shapes of constant width, but this conjecture was disproved by Campi et al. (1996), who instead showed that the minimum-volume shape of this type is a surface of revolution of a Reuleaux triangle through one of its symmetry axes.

[edit] References

Bonnesen, Tommy and Fenchel, Werner (1934). Theorie der konvexen Körper. Springer-Verlag, 127–139.

Campi, Stefano, Colesanti, Andrea, and Gronchi, Paolo (1996). "Minimum problems for volumes of convex bodies". Partial Differential Equations and Applications: Collected Papers in Honor of Carlo Pucci: 43–55, Lecture Notes in Pure and Applied Mathematics, no. 177, Marcel Dekker.