Absolute presentation of a group

In mathematics, an absolute presentation is one method of defining a group.^[1]

Recall that to define a group $G$ by means of a presentation, one specifies a set $S$ of generators so that every element of the group can be written as a product of some of these generators, and a set $R$ of relations among those generators. In symbols:

G\simeq \langle S\mid R\rangle .

Informally $G$ is the group generated by the set $S$ such that $r=1$ for all $r\in R$ . But here there is a tacit assumption that $G$ is the "freest" such group as clearly the relations are satisfied in any homomorphic image of $G$ . One way of being able to eliminate this tacit assumption is by specifying that certain words in $S$ should not be equal to $1.$ That is we specify a set $I$ , called the set of irrelations, such that $i\neq 1$ for all $i\in I.$

Formal definition edit

To define an absolute presentation of a group $G$ one specifies a set $S$ of generators and sets $R$ and $I$ of relations and irrelations among those generators. We then say $G$ has absolute presentation

\langle S\mid R,I\rangle .

provided that:

$G$ has presentation $\langle S\mid R\rangle .$
Given any homomorphism $h:G\rightarrow H$ such that the irrelations $I$ are satisfied in $h(G)$ , $G$ is isomorphic to $h(G)$ .

A more algebraic, but equivalent, way of stating condition 2 is:

2a. If

N\triangleleft G

is a non-trivial normal subgroup of

G

then

I\cap N\neq \left\{1\right\}.

Remark: The concept of an absolute presentation has been fruitful in fields such as algebraically closed groups and the Grigorchuk topology. In the literature, in a context where absolute presentations are being discussed, a presentation (in the usual sense of the word) is sometimes referred to as a relative presentation, which is an instance of a retronym.

Example edit

The cyclic group of order 8 has the presentation

\langle a\mid a^{8}=1\rangle .

But, up to isomorphism there are three more groups that "satisfy" the relation $a^{8}=1,$ namely:

\langle a\mid a^{4}=1\rangle

\langle a\mid a^{2}=1\rangle

and

\langle a\mid a=1\rangle .

However none of these satisfy the irrelation $a^{4}\neq 1$ . So an absolute presentation for the cyclic group of order 8 is:

\langle a\mid a^{8}=1,a^{4}\neq 1\rangle .

It is part of the definition of an absolute presentation that the irrelations are not satisfied in any proper homomorphic image of the group. Therefore:

\langle a\mid a^{8}=1,a^{2}\neq 1\rangle

Is not an absolute presentation for the cyclic group of order 8 because the irrelation $a^{2}\neq 1$ is satisfied in the cyclic group of order 4.

Background edit

The notion of an absolute presentation arises from Bernhard Neumann's study of the isomorphism problem for algebraically closed groups.^[1]

A common strategy for considering whether two groups $G$ and $H$ are isomorphic is to consider whether a presentation for one might be transformed into a presentation for the other. However algebraically closed groups are neither finitely generated nor recursively presented and so it is impossible to compare their presentations. Neumann considered the following alternative strategy:

Suppose we know that a group $G$ with finite presentation $G=\langle x_{1},x_{2}\mid R\rangle$ can be embedded in the algebraically closed group $G^{*}$ then given another algebraically closed group $H^{*}$ , we can ask "Can $G$ be embedded in $H^{*}$ ?"

It soon becomes apparent that a presentation for a group does not contain enough information to make this decision for while there may be a homomorphism $h:G\rightarrow H^{*}$ , this homomorphism need not be an embedding. What is needed is a specification for $G^{*}$ that "forces" any homomorphism preserving that specification to be an embedding. An absolute presentation does precisely this.

References edit

^ ^a ^b B. Neumann, The isomorphism problem for algebraically closed groups, in: Word Problems, Decision Problems, and the Burnside Problem in Group Theory, Amsterdam-London (1973), pp. 553–562.

[neumann-1] B. Neumann, The isomorphism problem for algebraically closed groups, in: Word Problems, Decision Problems, and the Burnside Problem in Group Theory, Amsterdam-London (1973), pp. 553–562.

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