Derived subgroup not is local powering-invariant

This article gives the statement, and possibly proof, of the fact that for a group, the subgroup obtained by applying a given subgroup-defining function (i.e., derived subgroup) does not always satisfy a particular subgroup property (i.e., local powering-invariant subgroup)
View subgroup property satisfactions for subgroup-defining functions

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View subgroup property dissatisfactions for subgroup-defining functions

Statement

It is possible to have a group ${\displaystyle G}$ such that the derived subgroup ${\displaystyle [G,G]}$ is not a local powering-invariant subgroup of ${\displaystyle G}$. Specifically, it is possible that there exists an element ${\displaystyle h\in [G,G]}$ and a natural number ${\displaystyle n}$ such that there exists a unique element ${\displaystyle w\in G}$ satisfying w^n = h</math> but ${\displaystyle w\notin H}$.

Proof

Example of the infinite dihedral group

Further information: infinite dihedral group

Consider the infinite dihedral group, given by the presentation:

${\displaystyle G:=⟨a,x\mid xa{x}^{-1}=a^{-1},x^2=e⟩}$

where ${\displaystyle e}$ denotes the identity of ${\displaystyle G}$. We find that:

${\displaystyle [G,G]=⟨a^2⟩}$

is an infinite cyclic group.

Now consider the element ${\displaystyle h=a^2}$. Let ${\displaystyle n=2}$. We note that all elements outside ${\displaystyle ⟨a⟩}$ have order two, hence any element ${\displaystyle w}$ with ${\displaystyle w^2=h}$ must be inside ${\displaystyle ⟨a⟩}$. The only possibility is thus ${\displaystyle w=a}$, which is outside ${\displaystyle H}$. Thus, the element ${\displaystyle h=a^2}$ has a unique square root in ${\displaystyle G}$, but this is not in ${\displaystyle H}$, completing the proof.

Example of a central product

Further information: semidirect product of UT(3,Z) and Z identifying center with 2Z