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The automorphism group of the symmetric group $S_n$ is $S_n$ when $n$ is not $2$ or $6$, in which cases it is respectively $1$ and the semidirect product of $S_6$ with the (cyclic) group of order $2$. (For this famous outer automorphism, see for instance wikipedia or Baez's thoughts on the number $6$.)

On the other hand, $S_2$ is the automorphism group of $Z_3$, $Z_4$ and $Z_6$ (and only those groups among finite groups). Hence my question: is $S_6$ the automorphism group of a group? of a finite group?

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4 Answers 4

up vote 67 down vote accepted

S_6 is not the automorphism group of a finite group. See H.K. Iyer, "On solving the equation Aut(X)=G", Rocky Mountain J. Math. 9 (1979), no. 4, 653--670, available online here.

This paper proves that for any finite group G, there are finitely many finite groups X with Aut(X)=G, and it explicitly solves the equation for some specific values of G. In particular, Theorem 4.4 gives the complete solution for G a symmetric group, and when n=6 there are no such X.

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The link is dead. A working one is . –  Emil Jeřábek Apr 15 '11 at 16:49

It's probably worth pointing to

Belolipetsky, Mikhail; Lubotzky, Alexander. Finite groups and hyperbolic manifolds. Invent. Math. 162 (2005), no. 3, 459-472. MR2198218.

where it is shown that for every finite group G, there's an infinite group Gamma with Out(Gamma) = G.

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There's a stronger result <a href="…; for countable groups. –  Qiaochu Yuan Oct 19 '09 at 19:15

On the other hand, S_6 is isomorphic to Sp_4(F_2), so that it is an automorphism group in another category (other than groups or sets). This automorphism is exhibited by looking at the 2-torsion of the Jacobian of a hyperelliptic curve H of genus 2 (if H is given by y^2 = f(x), with f of degree 6, then 15 non-trivial two torsion points are given [as a Galois module] by differences of roots of f; see the wiki page for Kummer surface).

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You mean Sp_4(F_2), I am sure, - SL_4(F_2) is simply too big to be S_6. –  Vladimir Dotsenko Nov 3 '09 at 22:59

There is a whole array of results, going back to G. Birkhoff at 1930s saying that every group is an automorphism group of some universal algebra (or some universal algebra inside some class).
(This really should be merely a comment to the previous answer, but I am still not reputable enough to leave comments).

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