Metabelian group

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In mathematics, a metabelian group is a group whose commutator subgroup is abelian. Equivalently, a group G is metabelian if and only if there is an abelian normal subgroup A such that the quotient group G/A is abelian.

Subgroups of metabelian groups are metabelian, as are images of metabelian groups over group homomorphisms. Metabelian groups are solvable.

[edit] Examples

Any dihedral group is metabelian, as it has a cyclic normal subgroup of index 2. More generally, any generalized dihedral group is metabelian, as it has an abelian normal subgroup of index 2.

If F_q is a finite field with q elements, the group of affine maps $x \mapsto ax+b$ (where a ≠ 0) acting on F_q is metabelian. Here the abelian normal subgroup is the group of pure translations $x\mapsto x+b$ (a group of order q ), its abelian quotient group is isomorphic to the group of homotheties $x\mapsto ax$ (a cyclic group of order q − 1 ).

The finite Heisenberg group H_3,p of order p³ (see the third example Heisenberg group modulo p in the examples section) is metabelian. The same is true for any Heisenberg group defined over a ring (group of upper-triangular 3 × 3 matrices with entries in a commutative ring).

The symmetric group on four letters S₄ is solvable but is not metabelian because its commutator subgroup is the alternating group A₄ which is not abelian.

[edit] External links

Ryan J. Wisnesky, Solvable groups (subsection Metabelian Groups)

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Categories: Algebra stubs | Solvable groups | Properties of groups

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