Algebraic group

The mathematical term of the algebraic group represents the synthesis of group theory and algebraic geometry . A central example is the group of invertible n × n matrices .

definition

An algebraic group is a group object in the category of algebraic varieties over a solid body , d. H. an affine algebraic variety over a field together with ${\ displaystyle G}$${\ displaystyle k}$

• a morphism (multiplication)${\ displaystyle m \ colon G \ times G \ to G}$
• a morphism (inverse element)${\ displaystyle i \ colon G \ to G}$
• and a distinguished point (neutral element),${\ displaystyle e \ in G (k)}$

so that the following conditions are met:

• Associative law : ;${\ displaystyle m \ circ (m \ times \ mathrm {id} _ {G}) = m \ circ (\ mathrm {id} _ {G} \ times m)}$
• neutral element: ;${\ displaystyle m \ circ (\ mathrm {id} _ {G} \ times e) = \ mathrm {id} _ {G} = m \ circ (e \ times \ mathrm {id} _ {G})}$
• inverse element: ; here is the inclusion of the diagonal ( ) and the structural morphism.${\ displaystyle m \ circ (i \ times \ mathrm {id} _ {G}) \ circ \ Delta _ {G} = e \ circ \ xi = m \ circ (\ mathrm {id} _ {G} \ times i) \ circ \ Delta _ {G}}$${\ displaystyle \ Delta _ {G} \ colon G \ to G \ times G}$${\ displaystyle g \ mapsto (g, g)}$${\ displaystyle \ xi \ colon G \ to Spec (k)}$

These conditions are equivalent to the requirement that for every - scheme on the set of - valued points define the structure of an (ordinary) group. ${\ displaystyle (m, i, e)}$${\ displaystyle k}$ ${\ displaystyle T}$${\ displaystyle G (T)}$${\ displaystyle T}$

• The additive group : with addition as a group structure. In particular for is the affine line with addition.${\ displaystyle \ mathbb {G} _ {\ mathrm {a}}}$${\ displaystyle \ mathbb {G} _ {\ mathrm {a}} (T) = \ Gamma (T, {\ mathcal {O}} _ {T})}$${\ displaystyle T = k}$${\ displaystyle \ mathbb {G} _ {\ mathrm {a}} = (k, +)}$${\ displaystyle \ mathrm {A} ^ {1}}$
• The multiplicative group : with multiplication as a group structure. In particular for is the open subset with multiplication.${\ displaystyle \ mathbb {G} _ {\ mathrm {m}}}$${\ displaystyle \ mathbb {G} _ {\ mathrm {m}} (T) = \ Gamma (T, {\ mathcal {O}} _ {T} ^ {\ times})}$${\ displaystyle T = k}$${\ displaystyle \ mathbb {G} _ {\ mathrm {m}} = (k ^ {\ times}, \ times)}$${\ displaystyle \ mathrm {A} ^ {1} - \ left \ {0 \ right \}}$
• The general linear group : ; The right side denotes the group of invertible matrices with entries in the ring . can be identified with.${\ displaystyle \ mathrm {GL} _ {n}}$${\ displaystyle \ mathrm {GL} _ {n} (T) = \ mathrm {GL} _ {n} (\ Gamma (T, {\ mathcal {O}} _ {T}))}$${\ displaystyle n \ times n}$${\ displaystyle \ Gamma (T, {\ mathcal {O}} _ {T})}$${\ displaystyle \ mathrm {GL} _ {1}}$${\ displaystyle \ mathbb {G} _ {\ mathrm {m}}}$
• The core of a morphism of algebraic groups is again an algebraic group. For example is an algebraic group.${\ displaystyle f: G \ rightarrow H}$${\ displaystyle \ mathrm {SL} _ {n} (T) = ker (det-1)}$
• Elliptic curves or, more generally, Abelian varieties .
• Zariski-closed subgroups of algebraic groups are again algebraic groups. Zariski-closed subgroups of are called linear algebraic groups . If an algebraic group is an affine variety, then it is a linear algebraic group.${\ displaystyle \ mathrm {GL} _ {n}}$
• Unipotent algebraic groups .

Every algebraic group over a field of characteristic 0 is (in a unique way) an extension of an Abelian variety by a linear algebraic group. That means that for every algebraic group there is a maximal linear algebraic subgroup , this is normal and the quotient is an Abelian variety : ${\ displaystyle G}$${\ displaystyle G_ {aff}}$${\ displaystyle A (G): = G / G_ {aff}}$

The picture is the Albanese picture . ${\ displaystyle G \ rightarrow A (G)}$