Hall's universal group

In algebra, Hall's universal group is a countable locally finite group, say U, which is uniquely characterized by the following properties.

It was defined by Philip Hall in 1959,[1] and has the universal property that all countable locally finite groups embed into it.

Construction

Take any group  \Gamma_0 of order  \geq 3 . Denote by  \Gamma_1 the group  S_{\Gamma_0} of permutations of elements of  \Gamma_0 , by \Gamma_2 the group

 S_{\Gamma_1}= S_{S_{\Gamma_0}} \,

and so on. Since a group acts faithfully on itself by permutations

 x\mapsto gx \,

according to Cayley's theorem, this gives a chain of monomorphisms

\Gamma_0 \hookrightarrow  \Gamma_1 \hookrightarrow \Gamma_2 \hookrightarrow \cdots . \,

A direct limit (that is, a union) of all  \Gamma_i is Hall's universal group U.

Indeed, U then contains a symmetric group of arbitrarily large order, and any group admits a monomorphism to a group of permutations, as explained above. Let G be a finite group admitting two embeddings to U. Since U is a direct limit and G is finite, the images of these two embeddings belong to \Gamma_i \subset U . The group \Gamma_{i+1}= S_{\Gamma_i} acts on \Gamma_i by permutations, and conjugates all possible embeddings G \hookrightarrow U.

References

  1. Hall, P. Some constructions for locally finite groups. J. London Math. Soc. 34 (1959) 305--319. MR 162845
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