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formal group (Rev #6, changes) in nLab

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Context

∞\infty-Lie theory

∞-Lie theory (higher geometry)

Background

Smooth structure

Higher groupoids

Lie theory

Lie theory

∞-Lie groupoids

∞-Lie groupoid
- strict ∞-Lie groupoid
- Lie groupoid
  - differentiable stack
  - orbifold
∞-Lie group
- Lie group
  - simple Lie group, semisimple Lie group
- Lie 2-group

∞-Lie algebroids

Formal Lie groupoids

formal group, formal groupoid

Cohomology

Homotopy

homotopy groups of a Lie groupoid

Related topics

∞-Chern-Weil theory

Examples

∞\infty-Lie groupoids

∞\infty-Lie groups

∞\infty-Lie algebroids

∞\infty-Lie algebras

Idea

A formal group is a group object internal to infinitesimal spaces. More general than Lie algebras, which are group objects in first order infinitesimal spaces, formal groups may be of arbitrary infinitesimal order. They sit between Lie algebras and finite Lie groups or algebraic groups.

Since infinitesimal spaces are typically modeled as formal duals to algebras, formal groups are typically conceived as group objects in formal duals to power series algebras.

Formal group laws

One of the oldest formalisms is the formalism of formal group laws (early study by Bochner and Lazard), which are a version of representing a group operation in terms of coefficients of the formal power series rings. A formal group law of dimension nn is given by a set of nn power series F iF_i of 2n2n variables x 1,…,x n,y 1,…,y nx_1,\ldots,x_n,y_1,\ldots,y_n such that (in notation x=(x 1,…,x n)x=(x_1,\ldots,x_n), y=(y 1,…,y n)y=(y_1,\ldots,y_n), F(x,y)=(F 1(x,y),…,F n(x,y))F(x,y) = (F_1(x,y),\ldots,F_n(x,y)))

F(x,F(y,z))=F(F(x,y),z) F(x,F(y,z))=F(F(x,y),z)

F i(x,y)=x i+y i+higherorderterms F_i(x,y) = x_i+y_i+\,\,higher\,\,order\,\,terms

Formal group laws of dimension 11 proved to be important in algebraic topology, especially in the study of cobordism, starting with the works of Novikov, Buchstaber and Quillen; among the generalized cohomology theories the complex cobordism is characterized by the so-called universal group law; moreover the usage is recently paralleled in the theory of algebraic cobordism of Morel and Levine in algebraic geometry. Formal groups are also useful in local class field theory; they can be used to explicitly construct the local Artin map according to Lubin and Tate.

Formal group schemes

Much more general are formal group schemes from (Grothendieck)

Formal group schemes are simply the group objects in a category of formal schemes; however usually only the case of the formal spectra of complete kk-algebras is considered; this category is equivalent to the category of complete cocommutative kk-Hopf algebras.

Formal groups over an operad

For a generalization over operads see (Fresse).

Formal geometry is closely related also to the rigid analytic geometry.

(nlab remark: we should explain connections to the Witt rings, Cartier/Dieudonné modules).

References

Grothendieck et al. SGA III, vol. 1, Expose VIIB (P. Gabriel) ETUDE INFINITESIMALE DES SCHEMAS EN GROUPES (part B) 474-560Alexander Grothendieck et al. SGA III, vol. 1, Expose VIIB (P. Gabriel) ETUDE INFINITESIMALE DES SCHEMAS EN GROUPES (part B) 474-560

Benoit Fresse, Lie theory of formal groups over an operad, J. Alg. 202, 455–511, 1998, doi

Revision on April 13, 2011 at 20:32:30 by Urs Schreiber See the history of this page for a list of all contributions to it.