2-group
In mathematics, particularly the branch called category theory, a 2-group is a groupoid with a way to multiply objects, making it resemble a group. They are part of a larger hierarchy of n-groups. They were introduced by Hoàng Xuân Sính in the late 1960s under the name gr-categories,[1][2] and they are also known as categorical groups.
Definition
A 2-group is a monoidal category G in which every morphism is invertible and every object has a weak inverse. (Here, a weak inverse of an object x is an object y such that xy and yx are both isomorphic to the unit object.)
Strict 2-groups
Much of the literature focuses on strict 2-groups. A strict 2-group is a strict monoidal category in which every morphism is invertible and every object has a strict inverse (so that xy and yx are actually equal to the unit object).
A strict 2-group is a group object in a category of categories; as such, they could be called groupal categories. Conversely, a strict 2-group is a category object in the category of groups; as such, they are also called categorical groups. They can also be identified with crossed modules, and are most often studied in that form. Thus, 2-groups in general can be seen as a weakening of crossed modules.
Every 2-group is equivalent to a strict 2-group, although this can't be done coherently: it doesn't extend to 2-group homomorphisms[citation needed].
Examples
Given a (small) category C, we can consider the 2-group Aut(C). This is the monoidal category whose objects are the autoequivalences of C (i.e. equivalences F:C→C), whose morphisms are natural isomorphisms between such autoequivalences, and the multiplication of autoequivalences is given by their composition.
Given a topological space X and a point x in that space, there is a fundamental 2-group of X at x, written Π2(X,x). As a monoidal category, the objects are loops at x, with multiplication given by concatenation, and the morphisms are basepoint-preserving homotopies between loops, with these morphisms identified if they are themselves homotopic.
Properties
Weak inverses can always be assigned coherently:[3] one can define a functor on any 2-group G that assigns a weak inverse to each object, so that each object is related to its designated weak inverse by an adjoint equivalence in the monoidal category G.
Given a bicategory B and an object x of B, there is an automorphism 2-group of x in B, written AutB(x). The objects are the automorphisms of x, with multiplication given by composition, and the morphisms are the invertible 2-morphisms between these. If B is a 2-groupoid (so all objects and morphisms are weakly invertible) and x is its only object, then AutB(x) is the only data left in B. Thus, 2-groups may be identified with one-object 2-groupoids, much as groups may be identified with one-object groupoids and monoidal categories may be identified with one-object bicategories.
If G is a strict 2-group, then the objects of G form a group, called the underlying group of G and written G0. This will not work for arbitrary 2-groups; however, if one identifies isomorphic objects, then the equivalence classes form a group, called the fundamental group of G and written π1(G). (Note that even for a strict 2-group, the fundamental group will only be a quotient group of the underlying group.)
As a monoidal category, any 2-group G has a unit object IG. The automorphism group of IG is an abelian group by the Eckmann–Hilton argument, written Aut(IG) or π2(G).
The fundamental group of G acts on either side of π2(G), and the associator of G (as a monoidal category) defines an element of the cohomology group H3(π1(G),π2(G)). In fact, 2-groups are classified in this way: given a group π1, an abelian group π2, a group action of π1 on π2, and an element of H3(π1,π2), there is a unique (up to equivalence) 2-group G with π1(G) isomorphic to π1, π2(G) isomorphic to π2, and the other data corresponding.
The element of H3(π1,π2) associated to a 2-group is sometimes called its Sinh invariant, as it was developed by Grothendieck's student Hoàng Xuân Sính.
Fundamental 2-group
As mentioned above, the fundamental 2-group of a topological space X and a point x is the 2-group Π2(X,x), whose objects are loops at x, with multiplication given by concatenation, and the morphisms are basepoint-preserving homotopies between loops, with these morphisms identified if they are themselves homotopic.
Conversely, given any 2-group G, one can find a unique (up to weak homotopy equivalence) pointed connected space (X,x) whose fundamental 2-group is G and whose homotopy groups πn are trivial for n > 2. In this way, 2-groups classify pointed connected weak homotopy 2-types. This is a generalisation of the construction of Eilenberg–Mac Lane spaces.
If X is a topological space with basepoint x, then the fundamental group of X at x is the same as the fundamental group of the fundamental 2-group of X at x; that is,
- [math]\displaystyle{ \pi_{1}(X,x) = \pi_{1}(\Pi_{2}(X,x)) .\! }[/math]
This fact is the origin of the term "fundamental" in both of its 2-group instances.
Similarly,
- [math]\displaystyle{ \pi_{2}(X,x) = \pi_{2}(\Pi_{2}(X,x)) .\! }[/math]
Thus, both the first and second homotopy groups of a space are contained within its fundamental 2-group. As this 2-group also defines an action of π1(X,x) on π2(X,x) and an element of the cohomology group H3(π1(X,x),π2(X,x)), this is precisely the data needed to form the Postnikov tower of X if X is a pointed connected homotopy 2-type.
See also
Notes
- ↑ Hoàng, Xuân Sính (1975), "Gr-catégories", Thesis, http://w5.mathematik.uni-stuttgart.de/fachbereich/Kuenzer/Kuenzer/sinh.html
- ↑ Baez, John C. (2023). "Hoàng Xuân Sính's thesis: categorifying group theory". arXiv:2308.05119 [math.CT].
- ↑ Baez Lauda 2004
References
- "Higher-dimensional algebra V: 2-groups", Theory and Applications of Categories 12: 423–491, 2004, http://www.tac.mta.ca/tac/volumes/12/14/12-14.pdf
- Baas, Nils; Friedlander, Eric; Jahren, Bjørn et al., eds. (2009), "The classifying space of a topological 2-group", Algebraic Topology. The Abel Symposium 2007, Springer, Berlin, pp. 1–31
- "The classifying space of a crossed complex", Mathematical Proceedings of the Cambridge Philosophical Society 110 (1): 95–120, July 1991, doi:10.1017/S0305004100070158, Bibcode: 1991MPCPS.110...95B
- Nonabelian algebraic topology: filtered spaces, crossed complexes, cubical homotopy groupoids, EMS Tracts in Mathematics, 15, August 2011, doi:10.4171/083, ISBN 978-3-03719-083-8
- Pfeiffer, Hendryk (2007), "2-Groups, trialgebras and their Hopf categories of representations", Advances in Mathematics 212 (1): 62–108, doi:10.1016/j.aim.2006.09.014
- Cegarra, Antonio Martínez; Heredia, Benjamín A.; Remedios, Josué (2012), "Double groupoids and homotopy 2-types", Applied Categorical Structures 20 (4): 323–378, doi:10.1007/s10485-010-9240-1
External links
- 2-group in nLab
- 2008 Workshop on Categorical Groups at the Centre de Recerca Matemàtica
Original source: https://en.wikipedia.org/wiki/2-group.
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