Center of dihedral group:D8

This article is about a particular subgroup in a group, up to equivalence of subgroups (i.e., an isomorphism of groups that induces the corresponding isomorphism of subgroups). The subgroup is (up to isomorphism) cyclic group:Z2 and the group is (up to isomorphism) dihedral group:D8 (see subgroup structure of dihedral group:D8).
The subgroup is a normal subgroup and the quotient group is isomorphic to Klein four-group.
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This article discuss the dihedral group of order eight and its center, which is a cyclic group of order two.

The dihedral group of order eight is defined as:

${\displaystyle G:=\langle a,x\mid a^{4}=x^{2}=e,xax=a^{-1}\rangle }$.

and the center is the cyclic subgroup ${\displaystyle H:=\{a^{2},e\}=\langle a^{2}\rangle }$.

Cosets

The subgroup has the following four cosets:

${\displaystyle \!\{e,a^{2}\},\qquad \{x,a^{2}x\},\qquad \{a,a^{3}\},\qquad \{ax,a^{3}x\}}$

Complements

The subgroup ${\displaystyle H}$ has no permutable complement and also has no lattice complement.

Properties related to complementation

Effect of subgroup operators

Subgroup-defining functions

The subgroup is a characteristic subgroup of the whole group and arises as a result of many subgroup-defining functions on the whole group. Some of these are given below.

Subgroup-defining function	Meaning in general	Why it takes this value	GAP verification (set G := DihedralGroup(8); H := Center(G);) -- see more at #GAP implementation
center	set of elements that commute with every element	To see that every element of ${\displaystyle H}$ is in the center, note that ${\displaystyle a^{2}}$ commutes with both ${\displaystyle a}$ and ${\displaystyle x}$. To see that no other element is in the center, note that ${\displaystyle a}$ and ${\displaystyle x}$ do not commute.	Definitional
derived subgroup	subgroup generated by commutators of all pairs of elements in the group, smallest subgroup with abelian quotient	The quotient (called the abelianization) is ${\displaystyle G/H}$, which is isomorphic to Klein four-group. No smaller subgroup works, because the quotient by the trivial subgroup is isomorphic to ${\displaystyle G}$, which is non-abelian.	H = DerivedSubgroup(G); using DerivedSubgroup
socle	subgroup generated by all the minimal normal subgroups	It is the unique minimal normal subgroup (hence is also a monolith). In general, for a finite ${\displaystyle p}$-group, the socle is ${\displaystyle \mho ^{1}(Z(G))}$.	H = Socle(G); using Socle
Frattini subgroup	intersection of all the maximal subgroups	${\displaystyle H}$ is the intersection of ${\displaystyle \langle a\rangle ,\langle a^{2},x\rangle ,\langle a^{2},ax\rangle }$.	H = Socle(G); using Socle
first agemo subgroup	subgroup generated by all ${\displaystyle p^{th}}$ powers, where ${\displaystyle p}$ is the underlying prime (in this case 2)	${\displaystyle \mho ^{1}(G)=H}$. In other words, it is the subgroup generated by the squares. In this case, it is precisely' the set of squares.	H = Agemo(G,2,1); using Agemo
ZJ-subgroup	center of the join of abelian subgroups of maximum order	The join of abelian subgroups of maximum order (the Thompson subgroup) is the whole group dihedral group:D8, so its center is ${\displaystyle H}$.

Subgroup properties

Invariance under automorphisms and endomorphisms

Property	Meaning	Satisfied?	Explanation
normal subgroup	invariant under inner automorphisms	Yes	center is normal
characteristic subgroup	invariant under all automorphisms	Yes	center is characteristic, derived subgroup is characteristic
fully invariant subgroup	invariant under all endomorphisms	Yes	derived subgroup is fully invariant, agemo subgroups are fully invariant
verbal subgroup	generated by set of words	Yes	derived subgroup is verbal, agemo subgroups are verbal
normal-isomorph-free subgroup	no other isomorphic normal subgroup	Yes
isomorph-free subgroup, isomorph-containing subgroup	No other isomorphic subgroups	No	There are other subgroups of order two.
isomorph-normal subgroup	Every isomorphic subgroup is normal	No	There are other subgroups of order two that are not normal: ${\displaystyle \langle x\rangle }$ etc.
homomorph-containing subgroup	contains all homomorphic images	No	There are other subgroups of order two.
1-endomorphism-invariant subgroup	invariant under all 1-endomorphisms of the group	Yes	It is precisely the set of squares, which must therefore go to squares under 1-endomorphisms
1-automorphism-invariant subgroup	invariant under all 1-automorphisms of the group	Yes	Follows from being 1-endomorphism-invariant.
quasiautomorphism-invariant subgroup	invariant under all quasiautomorphisms	Yes	Follows from being 1-automorphism-invariant

Centrality and related properties