Contents

Definition

A group is an algebraic structure consisting of a set $G$ and a binary operation $\star$ that satisfies the group axioms, being:

• associativity: $\forall a,b,c \in G: (a \star b) \star c = a \star (b \star c)$
• identity: $\exists e \in G, \forall a \in G: e \star a = a \star e = a$
• inverse: $\forall a \in G, \exists a^{-1} \in G: a \star a^{-1} = a^{-1} \star a = e$

It follows that the inverse $a^{-1}$ is unique for all $a$ and $G$ is non-empty.

In a broader sense, a group is a monoid in which every element has a (necessarily unique) inverse. When written with a view toward group objects (see Internalization below), one should rather say that a group is a monoid together with an inversion operation.

An abelian group is a group where the order in which two elements are multiplied is irrelevant. That is, it satisfies commutativity: $\forall a,b \in G : a \star b = b \star a$.

Delooping

To some extent, a group “is” a groupoid with a single object, or more precisely a pointed groupoid with a single object.

The delooping of a group $G$ is a groupoid $\mathbf{B} G$ with

• $Obj(\mathbf{B}G) = \{\bullet\}$

• $Hom_{\mathbf{B}G}(\bullet, \bullet) = G$.

Since for $G, H$ two groups, functors $\mathbf{B}G \to \mathbf{B}H$ are canonically in bijection with group homomorphisms $G \to H$, this gives rise to the following statement:

Let Grpd be the 1-category whose objects are groupoids and whose morphisms are functors (discarding the natural transformations). Let Grp be the category of groups. Then the delooping functor

is a full and faithful functor. In terms of this functor we may regard groups as the full subcategory of groupoids on groupoids with a single object.

It is in this sense that a group really is a groupoid with a single object.

But notice that it is unnatural to think of Grpd as a 1-category. It is really a 2-category, namely the sub-2-category of Cat on groupoids.

And the category of groups is not equivalent to the full sub-2-category of the 2-category of groupoids on one-object groupoids.

The reason is that two functors:

coming from two group homomorphisms $f_1, f_2 \colon G \to H$ are related by a natural transformation $\eta_h \colon \mathbf{B}f_1 \to \mathbf{B}f_2$ with single component $\eta_h \colon \bullet \mapsto h \in Mor(\mathbf{B} H)$ for each element $h \in H$ such that the homomorphisms $f_1$ and $f_2$ differ by the inner automorphism $Ad_h \colon H \to H$

To fix this, look at the category of pointed groupoids with pointed functors? and pointed natural transformations. Between group homomorphisms as above, only identity transformations are pointed, so $Grp$ becomes a full sub-$2$-category of $Grpd_*$ (one that happens to be a $1$-category). (Details may be found in the appendix to Lectures on n-Categories and Cohomology and should probably be added to pointed functor? and maybe also k-tuply monoidal n-category.)

Generalizations

Internalization

A group object internal to a category $C$ with finite products is an object $G$ together with maps $mult:G\times G\to G$, $id:1\to G$, and $inv:G\to G$ such that various diagrams expressing associativity, unitality, and inverses commute.

Equivalently, it is a functor $C^{op}\to Grp$ whose underlying functor $C^{op} \to Set$ is representable.

For example, a group object in Diff is a Lie group. A group object in Top is a topological group. A group object in Sch/S (the category or relative schemes) is an $S$-group scheme. And a group object in $CAlg^{op}$, where CAlg is the category of commutative algebras, is a (commutative) Hopf algebra.

A group object in Grp is the same thing as an abelian group (see Eckmann-Hilton argument), and a group object in Cat is the same thing as an internal category in Grp, both being equivalent to the notion of crossed module.

In higher categorical and homotopical contexts

Internalizing the notion of group in higher categorical and homotopical contexts yields various generalized notions. For instance

• a 2-group is a group object in Grpd

• an n-group is a group object internal to n-groupoids

• an ∞-group is a group object in an (∞,1)-category.

• a loop space is a group object in Top

• generally there is a notion of group object in an (infinity,1)-category.

And the notion of loop space object and delooping makes sense (at least) in any (infinity,1)-category.

Notice that the relation between group objects and deloopable objects becomes more subtle as one generalizes this way. For instance not every group object in an (infinity,1)-category is deloopable. But every group object in an (infinity,1)-topos is.

Weakened axioms

Following the practice of centipede mathematics, we can remove certain properties from the definition of group and see what we get:

• remove inverses to get monoids, then remove the identity to get semigroups;
• or remove associativity to get loops, then remove the identity to get quasigroups;
• or remove all of the above to get magmas;
• or instead allow (in a certain way) for the binary operation to be partial to get groupoids, then remove inverses to get categories, and then remove identities to get semicategories
• etc.

Examples

Special types and classes

• simple group

• finite group, progroup

  • classification of finite simple groups

  • sporadic finite simple groups

• abelian group

  • finite abelian group

• divisible group

• acyclic group

• topological group

  • discrete group

  • Kac-Moody group

• Lie group

• group of Lie type

Concrete examples

Standard examples of finite groups include the

• group of order 2$\;\mathbb{Z}/2\mathbb{Z}$

• symmetric group$\;\Sigma_n$

• cyclic group

• braid group$Br_n$

• Monster group

Standard examples of non-finite groups include thr

• group of integers $\mathbb{Z}$ (under addition);

• group of real numbers without 0 $\mathbb{R}\setminus \{0\}$ under multiplication.

• Prüfer group

Standard examples of Lie groups include the

• orthogonal group

• unitary group

• Spin group, spin^c group

Standard examples of topological groups include

• string group

Counterexamples

For more see counterexamples in algebra.

1. A non-abelian group, all of whose subgroups are normal:

   $$Q \coloneqq \langle a, b | a^4 = 1, a^2 = b^2, a b = b a^3 \rangle$$

2. A finitely presented, infinite, simple group

   Thomson's group T.

3. A group that is not the fundamental group of any 3-manifold.

   $$\mathbb{Z}^4$$

4. Two finite non-isomorphic groups with the same order profile.

   $$C_4 \times C_4, \qquad C_2 \times \langle a, b, | a^4 = 1, a^2 = b^2, a b = b a^3 \rangle$$

5. A counterexample to the converse of Lagrange's theorem.

   The alternating group $A_4$ has order $12$ but no subgroup of order $6$.

6. A finite group in which the product of two commutators is not a commutator.

   $$G = \langle (a c)(b d), (e g)(f h), (i k)(j l), (m o)(n p), (a c)(e g)(i k), (a b)(c d)(m o), (e f)(g h)(m n)(o p), (i j)(k l)\rangle \subseteq S_{16}$$

Related concepts

• 2-group

• n-group

• ∞-group

• monoid, monoid object,

• group, group object

  • discrete group

    • order of a group

      • p-primary group

    • finite group, profinite group

    • finitely generated group

  • subgroup

    • torsion subgroup

    • stabilizer, centralizer, normalizer

  • isogeny

  • coset, coset space

  • abelian group, anabelian group,

    • group completion

  • group commutator, commutator subgroup, abelianization

  • group character

  • group cohomology

  • group extension

  • normed group, bornological group

  • topological group, Lie group,

  • loop group

  • cogroup

  • multivalued group

  • is a commutative pregroup as mentioned in pregroup grammar

• ring, ring object

• automorphism group, automorphism 2-group, automorphism ∞-group,

  • group of bisections

• center, center of an ∞-group,

• inner automorphism group

• outer automorphism group, outer automorphism ∞-group

• group presentation

• groupal setoid

Literature

For more see also the references at group theory.

The terminology “group” was introduced (for what today would more specifically be called permutation groups) in

• Évariste Galois, letter to Auguste Chevallier, (May 1832)

The original article that gives a definition equivalent to the modern definition of a group:

• Heinrich Weber, Beweis des Satzes, dass jede eigentlich primitive quadratische Form unendlich viele Primzahlen darzustellen fähig ist, Mathematische Annalen 20:3 (1882), 301–329 (doi:10.1007/bf01443599)

Introduction of group theory into (quantum) physics (cf. Gruppenpest):

• Hermann Weyl, §III in: Gruppentheorie und Quantenmechanik, S. Hirzel, Leipzig (1931), translated by H. P. Robertson: The Theory of Groups and Quantum Mechanics, Dover (1950) [ISBN:0486602699, ark:/13960/t1kh1w36w]

Textbook account in relation to applications in physics:

• Shlomo Sternberg, Group Theory and Physics, Cambridge University Press 1994 (ISBN:9780521558853)

See also:

• Wikipedia, Group_(mathematics)

• bananaspace, 群 (Chinese)

Formalization of group structure in dependent type theory:

in Coq:

• Farida Kachapova, Formalizing groups in type theory [arXiv:2102.09125]

and with the univalence axiom

• unimath -> UniMath.Algebra.Groups

in Agda:

• agda-unimath -> group-theory.groups

• Martín Escardó, Groups, §3.33.10 in: Introduction to Univalent Foundations of Mathematics with Agda [arXiv:1911.00580, webpage]

in cubical Agda:

• 1lab: Algebra.Group

in Lean:

• Lean Community –> mathlib –> algebra.group.defs –> group

Exposition in a context of homotopy type theory:

• Egbert Rijke, Section 19 in: Introduction to Homotopy Type Theory, Cambridge Studies in Advanced Mathematics, Cambridge University Press [arXiv:2212.11082]

Alternative discussion (under looping and delooping) of groups in homotopy type theory as pointed connected homotopy 1-types:

• Marc Bezem, Ulrik Buchholtz, Pierre Cagne, Bjørn Ian Dundas, Daniel R. Grayson: Chapter 4 of: Symmetry (2021) [pdf]