In this section
G will denote a
finite group, though some aspects generalize to
locally finite groups and to
profinite groups.
Definition For a
prime p, the '''
p-core'
of a finite group is defined to be its largest normal p
-subgroup. It is the normal core of every Sylow p-subgroup of the group. The p
-core of G
is often denoted O_p(G), and in particular appears in one of the definitions of the Fitting subgroup of a finite group. Similarly, the '
p′-core'
is the largest normal subgroup of G
whose order is coprime to p'' and is denoted O_{p'}(G). In the area of finite insoluble groups, including the
classification of finite simple groups, the 2′-core is often called simply the
core and denoted O(G). This causes only a small amount of confusion, because one can usually distinguish between the core of a group and the core of a subgroup within a group. The '''
p′,
p-core''', denoted O_{p',p}(G) is defined by O_{p',p}(G)/O_{p'}(G) = O_p(G/O_{p'}(G)). For a finite group, the
p′,
p-core is the unique largest normal
p-nilpotent subgroup. The
p-core can also be defined as the unique largest subnormal
p-subgroup; the
p′-core as the unique largest subnormal
p′-subgroup; and the
p′,
p-core as the unique largest subnormal
p-nilpotent subgroup. The
p′ and
p′,
p-core begin the '
upper p
-series'. For sets
π1,
π2, ...,
πn+1 of primes, one defines subgroups O
π1,
π2, ...,
πn+1(
G) by: :O_{\pi_1,\pi_2,\dots,\pi_{n+1}}(G)/O_{\pi_1,\pi_2,\dots,\pi_{n}}(G) = O_{\pi_{n+1}}( G/O_{\pi_1,\pi_2,\dots,\pi_{n}}(G) ) The upper
p-series is formed by taking
π2
i−1 =
p′ and
π2
i =
p; there is also a
lower p-series. A finite group is said to be '''
p-nilpotent'
if and only if it is equal to its own p
′,p
-core. A finite group is said to be '
p-soluble'
if and only if it is equal to some term of its upper p
-series; its '
p-length'
is the length of its upper p
-series. A finite group G
is said to be p-constrained for a prime p'' if C_G(O_{p',p}(G)/O_{p'}(G)) \subseteq O_{p',p}(G). Every nilpotent group is
p-nilpotent, and every
p-nilpotent group is
p-soluble. Every soluble group is
p-soluble, and every
p-soluble group is
p-constrained. A group is
p-nilpotent if and only if it has a '
normal p
-complement', which is just its
p′-core.
Significance Just as normal cores are important for
group actions on sets,
p-cores and
p′-cores are important in
modular representation theory, which studies the actions of groups on
vector spaces. The
p-core of a finite group is the intersection of the kernels of the
irreducible representations over any field of characteristic
p. For a finite group, the
p′-core is the intersection of the kernels of the ordinary (complex) irreducible representations that lie in the principal
p-block. For a finite group, the
p′,
p-core is the intersection of the kernels of the irreducible representations in the principal
p-block over any field of characteristic
p. Also, for a finite group, the
p′,
p-core is the intersection of the centralizers of the abelian chief factors whose order is divisible by
p (all of which are irreducible representations over a field of size
p lying in the principal block). For a finite,
p-constrained group, an irreducible module over a field of characteristic
p lies in the principal block if and only if the
p′-core of the group is contained in the kernel of the representation.
Solvable radicals A related subgroup in concept and notation is the solvable radical. The
solvable radical is defined to be the largest
solvable normal subgroup, and is denoted O_\infty(G). There is some variance in the literature in defining the
p′-core of
G. A few authors in only a few papers (for instance
John G. Thompson's N-group papers, but not his later work) define the
p′-core of an insoluble group
G as the
p′-core of its solvable radical in order to better mimic properties of the 2′-core. ==References==