String duality: Difference between revisions

Latest revision as of 18:46, 16 March 2013

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

Every finite group G admits a monomorphism to U.

All such monomorphisms are conjugate by inner automorphisms of U.

It was defined by Philip Hall in 1959.^[1]

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

↑ Hall, P. Some constructions for locally finite groups. J. London Math. Soc. 34 (1959) 305--319. Template:MathSciNet

[1] Hall, P. Some constructions for locally finite groups. J. London Math. Soc. 34 (1959) 305--319. Template:MathSciNet

[1]

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-The author is known as Araceli Gulledge. I've always cherished residing in Idaho. The thing she adores most is to perform handball but she can't make it her occupation. Bookkeeping has been his day job for a while.<br><br>My blog; [http://Www.Creativecats.com/UserProfile/tabid/331/userId/19522/Default.aspx Www.Creativecats.com]
+In [[algebra]], '''Hall's universal group''' is
+a  countable [[locally finite group]], say ''U'', which is uniquely
+characterized by the following properties.
+* Every finite group ''G'' admits a [[monomorphism]] to ''U''.
+* All such monomorphisms are conjugate by [[inner automorphism]]s of ''U''.
+It was defined by [[Philip Hall]] in 1959.<ref>Hall, P.
+''Some constructions for locally finite groups.''
+J. London Math. Soc. '''34''' (1959) 305--319. {{MathSciNet | id = 162845}}</ref>
+== Construction ==
+Take any group <math> \Gamma_0 </math> of order <math> \geq 3 </math>.
+Denote by <math> \Gamma_1 </math> the group  <math> S_{\Gamma_0}</math>
+of [[permutation]]s of elements of <math> \Gamma_0 </math>, by
+<math>\Gamma_2 </math> the group
+:<math> S_{\Gamma_1}= S_{S_{\Gamma_0}} \, </math>
+and so on. Since a group acts faithfully on itself by permutations
+:<math> x\mapsto gx \, </math>
+according to [[Cayley's theorem]], this gives a chain of monomorphisms
+:<math>\Gamma_0 \hookrightarrow  \Gamma_1 \hookrightarrow \Gamma_2 \hookrightarrow \cdots . \, </math>
+A [[direct limit]] (that is, a union) of all <math> \Gamma_i</math>
+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 [[symmetric group|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
+<math>\Gamma_i \subset U </math>. The group
+<math>\Gamma_{i+1}= S_{\Gamma_i}</math> acts on <math>\Gamma_i</math>
+by permutations, and conjugates all possible embeddings
+<math>G \hookrightarrow U</math>.
+==References==
+<references />
+[[Category:Infinite group theory]]
+[[Category:Permutation groups]]

String duality: Difference between revisions

Latest revision as of 18:46, 16 March 2013

Construction

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