Subgroup series

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In mathematics, specifically group theory, a subgroup series of a group is a chain of subgroups:

Contents

where is the trivial subgroup. Subgroup series can simplify the study of a group to the study of simpler subgroups and their relations, and several subgroup series can be invariantly defined and are important invariants of groups. A subgroup series is used in the subgroup method.

Subgroup series are a special example of the use of filtrations in abstract algebra.

Definition

Normal series, subnormal series

A subnormal series (also normal series, normal tower, subinvariant series, or just series) of a group G is a sequence of subgroups, each a normal subgroup of the next one. In a standard notation

There is no requirement made that Ai be a normal subgroup of G, only a normal subgroup of Ai+1. The quotient groups Ai+1/Ai are called the factor groups of the series.

If in addition each Ai is normal in G, then the series is called a normal series, when this term is not used for the weaker sense, or an invariant series.

Length

A series with the additional property that AiAi+1 for all i is called a series without repetition; equivalently, each Ai is a proper subgroup of Ai+1. The length of a series is the number of strict inclusions Ai<Ai+1. If the series has no repetition then the length is n.

For a subnormal series, the length is the number of non-trivial factor groups. Every nontrivial group has a normal series of length 1, namely , and any nontrivial proper normal subgroup gives a normal series of length 2. For simple groups, the trivial series of length 1 is the longest subnormal series possible.

Ascending series, descending series

Series can be notated in either ascending order:

or descending order:

For a given finite series, there is no distinction between an "ascending series" or "descending series" beyond notation. For infinite series however, there is a distinction: the ascending series

has a smallest term, a second smallest term, and so forth, but no largest proper term, no second largest term, and so forth, while conversely the descending series

has a largest term, but no smallest proper term.

Further, given a recursive formula for producing a series, the terms produced are either ascending or descending, and one calls the resulting series an ascending or descending series, respectively. For instance the derived series and lower central series are descending series, while the upper central series is an ascending series.

Noetherian groups, Artinian groups

A group that satisfies the ascending chain condition (ACC) on subgroups is called a Noetherian group, and a group that satisfies the descending chain condition (DCC) is called an Artinian group (not to be confused with Artin groups), by analogy with Noetherian rings and Artinian rings. The ACC is equivalent to the maximal condition: every non-empty collection of subgroups has a maximal member, and the DCC is equivalent to the analogous minimal condition.

A group can be Noetherian but not Artinian, such as the infinite cyclic group, and unlike for rings, a group can be Artinian but not Noetherian, such as the Prüfer group. Every finite group is clearly Noetherian and Artinian.

Homomorphic images and subgroups of Noetherian groups are Noetherian, and an extension of a Noetherian group by a Noetherian group is Noetherian. Analogous results hold for Artinian groups.

Noetherian groups are equivalently those such that every subgroup is finitely generated, which is stronger than the group itself being finitely generated: the free group on 2 or finitely more generators is finitely generated, but contains free groups of infinite rank.

Noetherian groups need not be finite extensions of polycyclic groups. [1]

Infinite and transfinite series

Infinite subgroup series can also be defined and arise naturally, in which case the specific (totally ordered) indexing set becomes important, and there is a distinction between ascending and descending series. An ascending series where the are indexed by the natural numbers may simply be called an infinite ascending series, and conversely for an infinite descending series. If the subgroups are more generally indexed by ordinal numbers, one obtains a transfinite series, [2] such as this ascending series:

Given a recursive formula for producing a series, one can define a transfinite series by transfinite recursion by defining the series at limit ordinals by (for ascending series) or (for descending series). Fundamental examples of this construction are the transfinite lower central series and upper central series.

Other totally ordered sets arise rarely, if ever, as indexing sets of subgroup series.[ citation needed ] For instance, one can define but rarely sees naturally occurring bi-infinite subgroup series (series indexed by the integers):

Comparison of series

A refinement of a series is another series containing each of the terms of the original series. Two subnormal series are said to be equivalent or isomorphic if there is a bijection between the sets of their factor groups such that the corresponding factor groups are isomorphic. Refinement gives a partial order on series, up to equivalence, and they form a lattice, while subnormal series and normal series form sublattices. The existence of the supremum of two subnormal series is the Schreier refinement theorem. Of particular interest are maximal series without repetition.

Examples

Maximal series

Equivalently, a subnormal series for which each of the Ai is a maximal normal subgroup of Ai+1. Equivalently, a composition series is a subnormal series for which each of the factor groups are simple.

Solvable and nilpotent

A nilpotent series exists if and only if the group is solvable.
A central series exists if and only if the group is nilpotent.

Functional series

Some subgroup series are defined functionally, in terms of subgroups such as the center and operations such as the commutator. These include:

p-series

There are series coming from subgroups of prime power order or prime power index, related to ideas such as Sylow subgroups.

Related Research Articles

In mathematics, the ascending chain condition (ACC) and descending chain condition (DCC) are finiteness properties satisfied by some algebraic structures, most importantly ideals in certain commutative rings. These conditions played an important role in the development of the structure theory of commutative rings in the works of David Hilbert, Emmy Noether, and Emil Artin. The conditions themselves can be stated in an abstract form, so that they make sense for any partially ordered set. This point of view is useful in abstract algebraic dimension theory due to Gabriel and Rentschler.

In mathematics, more specifically in abstract algebra, the commutator subgroup or derived subgroup of a group is the subgroup generated by all the commutators of the group.

In mathematics, more specifically in the area of abstract algebra known as ring theory, a Noetherian ring is a ring that satisfies the ascending chain condition on left and right ideals; that is, given any increasing sequence of left ideals:

Solvable group

In mathematics, more specifically in the field of group theory, a solvable group or soluble group is a group that can be constructed from abelian groups using extensions. Equivalently, a solvable group is a group whose derived series terminates in the trivial subgroup.

Nilpotent group

In mathematics, specifically group theory, a nilpotent groupG is a group that has an upper central series that terminates with G. Equivalently, its central series is of finite length or its lower central series terminates with {1}.

Glossary of group theory

A group is a set together with an associative operation which admits an identity element and such that every element has an inverse.

In algebra, the nilradical of a commutative ring is the ideal consisting of the nilpotent elements of the ring,

In abstract algebra, a composition series provides a way to break up an algebraic structure, such as a group or a module, into simple pieces. The need for considering composition series in the context of modules arises from the fact that many naturally occurring modules are not semisimple, hence cannot be decomposed into a direct sum of simple modules. A composition series of a module M is a finite increasing filtration of M by submodules such that the successive quotients are simple and serves as a replacement of the direct sum decomposition of M into its simple constituents.

In abstract algebra, an Artinian ring is a ring that satisfies the descending chain condition on ideals; that is, there is no infinite descending sequence of ideals. Artinian rings are named after Emil Artin, who first discovered that the descending chain condition for ideals simultaneously generalizes finite rings and rings that are finite-dimensional vector spaces over fields. The definition of Artinian rings may be restated by interchanging the descending chain condition with an equivalent notion: the minimum condition.

In abstract algebra, an Artinian module is a module that satisfies the descending chain condition on its poset of submodules. They are for modules what Artinian rings are for rings, and a ring is Artinian if and only if it is an Artinian module over itself. Both concepts are named for Emil Artin.

In mathematics, a polycyclic group is a solvable group that satisfies the maximal condition on subgroups. Polycyclic groups are finitely presented, and this makes them interesting from a computational point of view.

Prüfer group

In mathematics, specifically in group theory, the Prüfer p-group or the p-quasicyclic group or p-group, Z(p), for a prime number p is the unique p-group in which every element has p different p-th roots.

In mathematics, a group is supersolvable if it has an invariant normal series where all the factors are cyclic groups. Supersolvability is stronger than the notion of solvability.

In abstract algebra, a chief series is a maximal normal series for a group.

In mathematics, specifically in the area of algebra known as group theory, the Fitting length measures how far a solvable group is from being nilpotent. The concept is named after Hans Fitting, due to his investigations of nilpotent normal subgroups.

In mathematics, especially in the fields of group theory and Lie theory, a central series is a kind of normal series of subgroups or Lie subalgebras, expressing the idea that the commutator is nearly trivial. For groups, this is an explicit expression that the group is a nilpotent group, and for matrix rings, this is an explicit expression that in some basis the matrix ring consists entirely of upper triangular matrices with constant diagonal.

In mathematics, the Krull–Schmidt theorem states that a group subjected to certain finiteness conditions on chains of subgroups, can be uniquely written as a finite direct product of indecomposable subgroups.

In the branch of abstract algebra called ring theory, the Akizuki–Hopkins–Levitzki theorem connects the descending chain condition and ascending chain condition in modules over semiprimary rings. A ring R (with 1) is called semiprimary if R/J(R) is semisimple and J(R) is a nilpotent ideal, where J(R) denotes the Jacobson radical. The theorem states that if R is a semiprimary ring and M is an R module, the three module conditions Noetherian, Artinian and "has a composition series" are equivalent. Without the semiprimary condition, the only true implication is that if M has a composition series, then M is both Noetherian and Artinian.

In mathematics, specifically group theory, finite groups of prime power order , for a fixed prime number and varying integer exponents , are briefly called finitep-groups.

In mathematics, an approximate group is a subset of a group which behaves like a subgroup "up to a constant error", in a precise quantitative sense. For example, it is required that the set of products of elements in the subset be not much bigger than the subset itself. The notion was introduced in the 2010s but can be traced to older sources in additive combinatorics.

References

  1. Ol'shanskii, A. Yu. (1979). "Infinite Groups with Cyclic Subgroups". Soviet Math. Dokl. 20: 343–346. (English translation of Dokl. Akad. Nauk SSSR, 245, 785787)
  2. Sharipov, R.A. (2009). "Transfinite normal and composition series of groups". arXiv: 0908.2257 [math.GR].