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rankAB

rankAb is a group-theoretic invariant that measures the free abelian rank of a group's abelianization. For a group G, its abelianization is Gn = G/[G,G], where [G,G] is the commutator subgroup. rankAb(G) is the rank of Gn as an abelian group, i.e., the maximal integer r such that Z^r embeds into Gn. Equivalently, rankAb(G) equals the torsion-free rank of Gn, and for finitely generated groups it equals the dimension of Gn ⊗ Q as a vector space over Q. If Gn is finite, rankAb(G) = 0.

Basic properties include that rankAb is invariant under group isomorphism and is monotone under surjective homomorphisms:

Computation often proceeds from a presentation. If G = ⟨x1, ..., xm | R⟩, then Gn is presented by

Relation to topology is standard: for a space X with π1(X) ≅ G, rankAb(G) equals the first Betti

Applications of rankAb include distinguishing groups with the same finite quotient structure and informing questions about

if
φ:
G
→
H
is
onto,
then
rankAb(G)
≥
rankAb(H).
For
common
classes,
free
groups
F_n
have
rankAb(F_n)
=
n,
since
F_n
abelianizes
to
Z^n.
Finite
groups
have
rankAb
=
0
because
their
abelianizations
are
finite.
If
G
is
abelian,
rankAb(G)
equals
the
rank
of
G
itself.
⟨x1,
...,
xm
|
commutativity,
R⟩,
and
rankAb(G)
equals
m
−
rank(M),
where
M
is
the
relation
matrix
obtained
from
the
abelianized
relations.
Smith
normal
form
provides
a
practical
method
to
determine
this
rank.
number
b1(X)
=
rank
H1(X;
Z).
Examples
include
G
=
Z^n
(rankAb
=
n)
and
G
=
S_n
(n
≥
3)
which
has
rankAb
=
0.
generating
sets
and
abelian
quotients.