Questions tagged [algebraic-groups]

For questions about groups which have additional structure as algebraic varieties (the vanishing sets of collections of polynomials) which is compatible with their group structure. These include both linear algebraic groups as well as abelian varieties.

Consider using with the (group-theory) tag.

This tag is for questions about algebraic groups. There are two main types of algebraic groups: linear algebraic groups and abelian varieties. The prototypical example of a linear algebraic group is $\mathrm{GL}_n$, the group of $n\times n$ matrices. The prototypical example of an abelian variety is an elliptic curve, which is the set of solutions to an equation $y^2 = x^3 + Ax + B$.

Over a field $k$, an algebraic group consists of (i) an underlying set $G$ defined as an algebraic subset of either affine space $G \subset \mathbb{A}^n_k$ (in the case of linear algebraic groups) or projective space $G \subset \mathbb{P}^n_k$ (in the case of abelian varieties) and (ii) a group operation called multiplication, which is a polynomial function $m\colon G \times G \to G$ satisfying axioms of associativity, invertibility, and identity. The set $G$ is referred to as an algebraic variety, and it is endowed with the Zariski topology, which is defined as the coarsest topology such that all subsets $Z$, which are cut out by the vanishing of a collection of polynomials, are closed. These closed subsets $Z \subset G$ are also algebraic varieties, called sub-varieties. If $Z$ is closed under the restriction of the multiplication map, i.e. if $m(Z \times Z) \subset Z$, then $Z$ also inherits a group structure and is called an algebraic subgroup of $G$.

Note that here we have not required a variety to be irreducible, which is a condition used by some authors. We have also not required $k$ to be algebraically closed, as some authors do.

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faithful irreducible representation of linear algebraic group over reals

Is it true that if a linear algebraic group defined over $\mathbb{R}$ has a faithful irreducible representation, then it is reductive?
Vanya
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Quotient of algebraic groups $SO_n/SO_{n-1}$

It is quite an elementary question but I need a little bit help to elaborate it. Let $\text{char}\,k\neq2$. I want to show that the quotient of algebraic groups $SO_n/SO_{n-1}$ is isomorphic to the affine variety…
jimbo
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on the condition "$G$ is defined over $\mathbb{Q}$"

This might be a stupid question, but I cannot understand the "technical condition" when studying some basics of arithmetic groups, that is an algebraic group is defined over $\mathbb{Q}$. Specifically, Borel-Harish-Chandra's theorem says that if $G$…
C.C.
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Weyl group of $B_n$ and $D_n$

Is it true that the Weyl group $W(D_n)$ is also a quotient of the Weyl group $W(B_n)$? One can see that $W(D_n)$ is a normal subgroup of $W(B_n)$ irrespective of $n$ even or odd.
Nutan
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A question about reductive groups's structure.

There is a flaw somewhere in the following argument but I can't track it. Take a reductive connected affine algebraic group $G$ : by definition, its unipotent radical $R_u(G)$ is trivial. One have the following (non trivial) result about reductive…
Pece
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why is Borel subgroup not nilpotent?

Let $G$ be a simple linear group group over an algebraically closed field $k$, and let $B$ be a maximal solvable subgroup. If things are happening over $\mathbb{C}$ then I know how to show that $B$ is not nilpotent: elements of torus lie subalgebra…
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$\mathscr{B}^S$ can be identified with a closed subgroup of $G/B$

There is a statement on page 149 of James E. Humphreys' Linear Algebraic Groups: Let $G$ be an algebraic group. $S \subseteq G$ is an arbitrary torus contained in a Borel subgroup $B$. $\mathscr{B}^S$ denotes the the set of Borel subgroups of $G$…
ShinyaSakai
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A connected algebraic group of positive dimension is semisimple if and only if it has no nontrivial closed connected commutative normal subgroup

Let $G$ be a connected algebraic group of positive dimension. Prove that $G$ is semisimple if and only if $G$ has no closed connected commutative normal subgroup except $e$. It is clear in one direction, given the definition of semisimple…
ShinyaSakai
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Questions about the differential of Ad.

In the book linear algebraic groups by Humphreys. Page 73, Lemma B says that for $x \in GL(n, K)$, $\mathbf{x} \in gl(n, K)$ we have $Ad x(\mathbf{x}) = x\mathbf{x}x^{-1}$. In the proof, the first line of the equations, it is said that for $T_{ij}$…
LJR
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If $G$ leaves stable a subspace $W$ of $K^n$, prove that $\mathfrak{g} \subseteq \mathfrak{gl}(n,K)$ does likewise

Let $G$ be a closed subgroup (algebraic group) of $GL(n,K)$. If $G$ leaves stable a subspace $W$ of $K^n$, prove that $\mathfrak{g} \subseteq \mathfrak{gl}(n,K)$ does likewise. Converse? Here, $K$ is an algebraically closed field. $\mathfrak{g}$,…
ShinyaSakai
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Questions about tangent maps of tangent spaces of algebraic groups.

Let $G, H$ be algebraic groups and $K$ an algebraic closed field. Suppose that we have a morhpism $f:G \to H$ and the corresponding morphism of functions $f^*:K[H] \to K[G]$ given by $\varphi \mapsto \varphi \circ f$. Here $K[G]$ is the group…
LJR
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How is the centralizer in $\mathrm{GL}_n(k)$ a torus

I have the following definition: Suppose that $g \in \mathrm{GL}_n(k)$ is regular and semisimple. Define $T_g := \mathrm{Cent}_{\mathrm{GL}_n(k)}(g)$ to be the centralizer of $g$ in $\mathrm{GL}_n(k)$. My advisor and I managed to proof that we have…
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$\mathbb{G_a}$ is being linear algebraic group, but first diagram does not commute?

Question: Why they are all assume it trivial, but I cannot make it commute the diagram in the first axiom of being, linear algebraic group (for $A=k[s]$). Definition 3.48.(ref.Mukai An Introduction to Invariants and Moduli (Cambridge Studies in…
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Maximal torus in the Borel subgroup is maximal in $G$.

Let $G$ be a linear algebraic group and $T\subset B\subset G$ where $T$ is torus and $B$ is a Borel subgroup of $G$. Suppose that $T$ is maximal in $B$. Then, how can I show that $T$ is also maximal in $G$? Many books take this for granted, and I…
PMJ
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Does an arbitrary algebraic group G possess a unique largest normal solvable subgroup?

On page 125 of Humphreys' "Linear Algebraic Groups," it states the following: "An arbitrary algebraic group G possesses a unique largest normal solvable subgroup." However, I am currently questioning this assertion. Finite groups have unique largest…
PMJ
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