Sphere eversion explained

Sphere eversion should not be confused with Sphere inversion.

In differential topology, sphere eversion is the process of turning a sphere inside out in a three-dimensional space (the word eversion means "turning inside out"). It is possible to smoothly and continuously turn a sphere inside out in this way (allowing self-intersections of the sphere's surface) without cutting or tearing it or creating any crease. This is surprising, both to non-mathematicians and to those who understand regular homotopy, and can be regarded as a veridical paradox; that is something that, while being true, on first glance seems false.

More precisely, let

f\colonS2\to\R3

be the standard embedding; then there is a regular homotopy of immersions

ft\colonS2\to\R3

such that ƒ0 = ƒ and ƒ1 = -ƒ.

History

An existence proof for crease-free sphere eversion was first created by .It is difficult to visualize a particular example of such a turning, although some digital animations have been produced that make it somewhat easier. The first example was exhibited through the efforts of several mathematicians, including Arnold S. Shapiro and Bernard Morin, who was blind. On the other hand, it is much easier to prove that such a "turning" exists, and that is what Smale did.

Smale's graduate adviser Raoul Bott at first told Smale that the result was obviously wrong . His reasoning was that the degree of the Gauss map must be preserved in such "turning"—in particular it follows that there is no such turning of S1 in R2. But the degrees of the Gauss map for the embeddings f and -f in R3 are both equal to 1, and do not have opposite sign as one might incorrectly guess. The degree of the Gauss map of all immersions of S2 in R3 is 1, so there is no obstacle. The term "veridical paradox" applies perhaps more appropriately at this level: until Smale's work, there was no documented attempt to argue for or against the eversion of S2, and later efforts are in hindsight, so there never was a historical paradox associated with sphere eversion, only an appreciation of the subtleties in visualizing it by those confronting the idea for the first time.

See h-principle for further generalizations.

Proof

Smale's original proof was indirect: he identified (regular homotopy) classes of immersions of spheres with a homotopy group of the Stiefel manifold. Since the homotopy group that corresponds to immersions of

S2

in

\R3

vanishes, the standard embedding and the inside-out one must be regular homotopic. In principle the proof can be unwound to produce an explicit regular homotopy, but this is not easy to do.

There are several ways of producing explicit examples and mathematical visualization:

Variations

S6

in seven-dimensional euclidean space

R7

admits eversion.[3] With an evident case of an 0-dimensional sphere

S0

(two distinct points) in a real line

R

and described above case of a two-dimensional sphere in

R3

there are only three cases when sphere

Sn

embedded in euclidean space

Rn+1

admits eversion.

See also

References

Bibliography

External links

Notes and References

  1. Web site: Outside In: Introduction. The Geometry Center. 21 June 2017.
  2. Analytic sphere eversion using ruled surfaces . 1711.10466 . Bednorz . Adam . Bednorz . Witold . Differential Geometry and Its Applications . 2019 . 64 . 59–79 . 10.1016/j.difgeo.2019.02.004 . 119687494 .
  3. Book: Goryunov, Victor V. . Local invariants of mappings of surfaces into three-space . 0-8176-3883-0 . 223–255 . Birkhäuser . Boston, Massachusetts . The Arnold–Gelfand mathematical seminars . 1997.