Glossary

12.1 Algebraic groups and group actions

6 min readjuly 30, 2024

Algebraic groups blend algebra and geometry, giving us powerful tools to study symmetries and transformations. They're like mathematical Swiss Army knives, helping us understand everything from simple shapes to complex geometric structures.

In this part, we'll see how these groups work and how they act on varieties. We'll explore their structure, learn about important examples, and see how they're used to solve real-world problems in math and beyond.

Algebraic groups and properties

Definition and basic structure

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  • An is a variety G equipped with morphisms for multiplication μ: G × G → G and inversion ι: G → G, satisfying the group axioms
  • The of an algebraic group is a distinguished point e in G
  • The group axioms (associativity, identity, inverses) hold in the category of varieties, meaning they are satisfied by the morphisms μ and ι
  • The multiplication map μ and the inversion map ι are required to be morphisms of varieties, ensuring compatibility between the group structure and the algebraic geometry of G

Examples of algebraic groups

  • The Gm is the variety A1{0}\mathbb{A}^1 \setminus \{0\} with multiplication (x,y)xy(x, y) \mapsto xy and inversion xx1x \mapsto x^{-1}
  • The Ga is the variety A1\mathbb{A}^1 with addition (x,y)x+y(x, y) \mapsto x + y and inversion xxx \mapsto -x
  • The general linear group GLn is the variety of invertible n×nn \times n matrices with matrix multiplication and inversion
  • The special linear group SLn is the of GLn consisting of matrices with determinant 1
  • Elliptic curves and abelian varieties are examples of projective algebraic groups

Structure of algebraic groups

Subgroups and quotients

  • A subgroup H of an algebraic group G is a closed subvariety that is also a subgroup in the group-theoretic sense
  • The identity component G0 of an algebraic group G is the connected component containing the identity element e
  • The quotient G/H of an algebraic group G by a H has a natural structure of an algebraic group induced by the group operations on G
  • The quotient morphism π: G → G/H is a morphism of algebraic groups with kernel H

Lie algebras and the exponential map

  • The g of an algebraic group G is the tangent space at the identity TeGT_e G, equipped with a Lie bracket operation [,]:g×gg[\cdot, \cdot]: g \times g \to g
  • The exp: g → G is a local isomorphism from a neighborhood of 0 in g to a neighborhood of e in G, relating the Lie algebra to the algebraic group
  • The differential of the multiplication map μ at (e, e) induces the Lie bracket on g, making it compatible with the group structure
  • The Ad: G → GL(g) describes the action of G on its Lie algebra by conjugation

Classification of algebraic groups

  • An algebraic group is solvable if it has a composition series with solvable quotients (successive extensions by Ga\mathbb{G}_a or Gm\mathbb{G}_m)
  • An algebraic group is unipotent if it has a composition series with unipotent quotients (successive extensions by Ga\mathbb{G}_a)
  • An algebraic group is if it has no non-trivial solvable normal subgroups
  • The expresses an algebraic group as an extension of a semisimple group by a
  • The classification of semisimple algebraic groups is related to the classification of root systems and Dynkin diagrams

Group actions on varieties

Definition and orbits

  • An action of an algebraic group G on a variety X is a morphism α: G × X → X satisfying the usual axioms: α(e,x)=x\alpha(e, x) = x and α(g,α(h,x))=α(gh,x)\alpha(g, \alpha(h, x)) = \alpha(gh, x)
  • The orbit of a point x in X under the G-action is the set G·x = {α(g,x) | g in G}, which is a locally closed subvariety of X
  • Orbits partition X into disjoint subvarieties, each isomorphic to a quotient of G by a stabilizer subgroup
  • The stabilizer subgroup Gx of a point x is the subgroup {g in G | α(g,x) = x}, which is a closed subgroup of G

Quotients and fibers

  • There is a bijective correspondence between orbits G·x and cosets of stabilizers G/Gx, given by gGxgxgG_x \mapsto g \cdot x
  • A G-action is transitive if it has only one orbit, meaning every point can be reached from any other point by the action of G
  • A G-action is free if all stabilizers are trivial, i.e., Gx={e}G_x = \{e\} for all x in X
  • A G-action is faithful if the map G → Aut(X) given by g(xgx)g \mapsto (x \mapsto g \cdot x) is injective
  • A geometric quotient of X by a G-action is a variety Y with a morphism π: X → Y constant on orbits, such that π induces a bijection between orbits and points of Y
  • Fibers of the quotient map π are the orbits of the G-action, and Y parameterizes the set of orbits

Algebraic groups for geometry

Symmetries and automorphisms

  • Algebraic groups can be used to study symmetries and automorphisms of algebraic varieties
  • The Aut(X) of a variety X is an algebraic group, often with a rich structure
  • Symmetries of X correspond to elements of Aut(X) or its subgroups, and can be used to simplify the study of X
  • The structure theory of algebraic groups helps classify certain types of varieties with large automorphism groups, e.g., toric varieties, spherical varieties, flag varieties

Homogeneous spaces and bundles

  • Group actions encode the geometry of homogeneous spaces, fiber bundles, and principal bundles in algebraic geometry
  • A is a variety X with a transitive action of an algebraic group G, e.g., projective spaces, Grassmannians, flag varieties
  • A over X is a variety E with a G-action and a G-invariant morphism π: E → X, such that π is locally trivial with fibers isomorphic to a fixed G-variety F
  • A is a G-equivariant bundle where the fibers are isomorphic to G acting on itself by multiplication
  • The quotient of E by the G-action is isomorphic to X, and E can be recovered from X and the cocycle defining the bundle

Representation theory and invariant theory

  • theory of algebraic groups provides tools for studying linear actions on vector spaces and sheaves
  • A representation of an algebraic group G is a morphism of algebraic groups ρ: G → GL(V) for some finite-dimensional vector space V
  • Representations can be used to construct G-equivariant sheaves and study their cohomology, which often has additional structure coming from the representation
  • describes polynomials and rational functions invariant under a , and their relations to quotients
  • The C[V]G\mathbb{C}[V]^G of a G-representation V is the subring of G-invariant polynomials, which is finitely generated by the Hilbert Basis Theorem
  • The V//GV // G is the variety Spec(C[V]G\mathbb{C}[V]^G), which parameterizes closed orbits of the G-action on V

Applications over finite fields

  • Algebraic groups over finite fields are used in coding theory, cryptography, and other applications
  • The states that the fixed points of a Frobenius endomorphism on a connected algebraic group over a finite field form a finite subgroup
  • Finite subgroups of algebraic groups over finite fields are used to construct error-correcting codes, such as Goppa codes and algebraic-geometric codes
  • Cryptographic protocols based on the hardness of the discrete logarithm problem or the Diffie-Hellman problem can be formulated using algebraic groups over finite fields
  • Algebraic groups over finite fields also appear in the study of zeta functions, L-functions, and other arithmetic invariants of varieties

Key Terms to Review (32)

Additive group: An additive group is a set equipped with an operation that combines any two elements to form a third element, satisfying specific properties such as closure, associativity, the existence of an identity element, and the presence of inverses. In the context of algebraic structures, additive groups play a crucial role in understanding how these structures operate under addition, leading to further exploration of group actions and algebraic groups.
Adjoint representation: The adjoint representation is a way to describe how a Lie algebra acts on itself via the adjoint action, which involves the commutation of elements. This representation captures the structure of the Lie algebra and is fundamental in understanding the behavior of algebraic groups and their actions. The adjoint representation is essential for studying the properties of algebraic groups, particularly in relation to their symmetries and transformations.
Algebraic Group: An algebraic group is a group that is also an algebraic variety, meaning it can be defined by polynomial equations and has a group structure that is compatible with its algebraic structure. These groups are studied in the context of both algebraic geometry and abstract algebra, allowing for the exploration of symmetry, group actions, and geometric properties within algebraic structures.
Automorphism Group: An automorphism group is a mathematical structure that consists of all the automorphisms of an object, such as a geometric shape or algebraic structure, along with the operation of composition. It captures how an object can be transformed while preserving its inherent properties, allowing for a better understanding of its symmetries and invariants. Automorphisms can reveal important structural insights and are essential in the study of algebraic groups and their actions on various spaces.
Chevalley's Theorem: Chevalley's Theorem states that a morphism from an algebraic group to an algebraic variety is a regular map if the group is defined over an algebraically closed field. This theorem plays a crucial role in understanding the actions of algebraic groups on varieties, highlighting the connection between algebraic groups and their representations. It provides essential insights into the structure of algebraic varieties under group actions, reinforcing the links between algebraic geometry and group theory.
Cohomological dimension: Cohomological dimension is a concept in algebraic geometry that measures the 'size' of the cohomology groups associated with a space or an algebraic variety, reflecting how complex it is to resolve sheaves over that space. It provides a way to understand the limitations of global sections and the effectiveness of covering by affine open sets, which is essential when analyzing actions of algebraic groups on varieties.
Exponential map: The exponential map is a mathematical tool that relates the tangent space of a manifold at a point to the manifold itself. It is crucial in understanding the structure of algebraic groups, especially when exploring their actions and relationships within algebraic geometry. The exponential map allows for the study of curves on the group by mapping vectors in the tangent space to actual points on the group, facilitating a connection between algebraic and geometric perspectives.
G-equivariant bundle: A g-equivariant bundle is a vector bundle over a geometric space that is compatible with the action of an algebraic group g, meaning that the group acts on both the base space and the fibers of the bundle in a coherent manner. This concept is significant because it allows us to study geometric structures while respecting the symmetries introduced by the group action, leading to richer mathematical insights.
Galois cohomology: Galois cohomology is a mathematical framework that studies the relationships between field extensions and Galois groups, specifically focusing on the cohomological properties of these groups. It connects algebraic geometry, number theory, and representation theory by examining how Galois groups act on various mathematical objects, allowing us to classify extensions and understand their structure through cohomological techniques. This theory is crucial in understanding symmetries and the classification of algebraic structures.
Git quotient: The git quotient refers to the process of forming a quotient by a group action on a variety, specifically in the context of algebraic geometry. When a group acts on an algebraic variety, the git quotient provides a way to construct a new variety that captures the orbit structure of the action, allowing for the analysis of the geometric and algebraic properties of the original space while factoring in the symmetry of the group action.
Gl(n): The term gl(n) refers to the general linear group of degree n, which consists of all n x n invertible matrices with entries from a given field, typically the field of real or complex numbers. This group plays a crucial role in various mathematical disciplines, including algebraic geometry, where it describes transformations that preserve linear structures. In the context of algebraic groups and group actions, gl(n) serves as a fundamental example of an algebraic group, illustrating how matrix operations can be understood within the framework of group theory.
Group action: A group action is a formal way of describing how a group interacts with a set by assigning to each element of the group a transformation of that set, while preserving the group structure. This concept helps understand symmetries and invariants in various mathematical contexts, particularly in algebraic geometry where algebraic groups act on varieties. The interaction between groups and sets through actions reveals important properties about the structures involved.
Homogeneous space: A homogeneous space is a type of space that looks the same at every point, meaning that its structure is uniform throughout. This property allows for the action of a group on the space to be consistent, meaning that for any two points in the space, there exists an element in the group that can map one point to the other. Homogeneous spaces often arise in the study of algebraic groups, where the action of these groups preserves the geometric and algebraic properties of the space.
Homomorphism: A homomorphism is a structure-preserving map between two algebraic structures, such as groups, rings, or vector spaces, that respects the operations defined on those structures. This means that if you apply the operation in the first structure and then map it to the second, you get the same result as if you mapped each element first and then applied the operation in the second structure. Homomorphisms help to connect different algebraic systems and show how they can behave similarly under certain operations.
Identity element: An identity element is a special type of element in a mathematical structure that, when combined with any other element in that structure, leaves the other element unchanged. This concept is crucial for understanding the behavior of algebraic structures like groups, where the identity element serves as a reference point for the group's operation, ensuring that every element can effectively interact within the system.
Invariant Theory: Invariant theory is a branch of mathematics that studies properties of objects that remain unchanged under certain transformations, particularly group actions. This theory is closely linked to algebraic groups and the ways they act on algebraic varieties, revealing insights into the structure of these varieties and the relationships between them.
Irreducibility: Irreducibility refers to the property of a polynomial or algebraic variety that cannot be factored into simpler components over the given field or ring. This concept is vital in understanding the structure of varieties, as it determines whether a variety can be expressed as a union of smaller varieties, influencing how we analyze their geometric and algebraic properties.
Jordan Decomposition: Jordan decomposition refers to the representation of a linear operator on a finite-dimensional vector space as the direct sum of its nilpotent part and a semisimple part. This concept is crucial in understanding the structure of algebraic groups, particularly when analyzing how group actions influence representations and the properties of the groups involved.
Lang-Steinberg Theorem: The Lang-Steinberg Theorem is a fundamental result in the study of algebraic groups that provides criteria for the existence of rational points on certain algebraic varieties. It establishes a relationship between the group of rational points of a linear algebraic group and its group actions, emphasizing how these structures interact within the realm of algebraic geometry.
Lie Algebra: A Lie algebra is a mathematical structure that captures the essence of the algebraic operations associated with Lie groups, which are groups that are also smooth manifolds. It consists of a vector space equipped with a binary operation called the Lie bracket, which satisfies bilinearity, antisymmetry, and the Jacobi identity. Lie algebras are fundamental in understanding the behavior of algebraic groups and their actions on various spaces.
Luna's Slice Theorem: Luna's Slice Theorem is a significant result in the theory of algebraic groups that provides a method for studying group actions on varieties through the concept of orbits and slices. It establishes that under certain conditions, the behavior of a group action can be analyzed by examining the action on a slice, which is a subvariety intersecting an orbit in a particular way. This theorem not only helps in understanding the local structure of group actions but also connects algebraic geometry to representation theory.
Multiplicative group: A multiplicative group is a set equipped with a binary operation, usually denoted as multiplication, that satisfies four fundamental properties: closure, associativity, the existence of an identity element, and the existence of inverses for each element in the set. In the context of algebraic groups, the multiplicative group can be seen as a specific type of algebraic group where the operation is multiplication, often used to describe solutions to polynomial equations and their symmetries.
Normal Subgroup: A normal subgroup is a subgroup that is invariant under conjugation by any element of the group, meaning that for any element in the group and any element in the subgroup, the result of conjugating the subgroup element remains in the subgroup. This property is essential because it allows for the formation of quotient groups, which helps in understanding the structure of larger groups through their simpler components. Normal subgroups play a key role in the study of group actions and algebraic groups, as they relate to the behavior of elements under these actions.
Principal g-bundle: A principal g-bundle is a mathematical structure that consists of a base space, a total space, and a group action, specifically for a Lie group g, that describes how the group acts on the fibers of the bundle. It provides a way to understand how various geometric objects can be related to symmetries represented by the group, facilitating the study of connections and curvature in geometry. Principal g-bundles play a crucial role in the theory of fiber bundles and algebraic geometry, connecting algebraic groups and their actions on varieties.
Reductive: In the context of algebraic groups, a reductive group is a type of algebraic group where every representation is completely reducible. This means that any linear representation can be decomposed into a direct sum of irreducible representations, making the structure of these groups particularly well-behaved and easier to study. Reductive groups play a significant role in understanding group actions and their implications in geometry and representation theory.
Representation: In algebraic geometry, representation refers to the way algebraic structures, such as algebraic groups, can be expressed through linear transformations on vector spaces. This concept connects algebraic groups to their action on various geometric objects, revealing important properties about symmetries and group actions.
Ring of invariants: The ring of invariants is a mathematical structure that consists of polynomials or functions that remain unchanged under the action of a given algebraic group. This concept plays a crucial role in understanding how algebraic groups interact with varieties, allowing us to classify and analyze geometric properties while respecting symmetries inherent to the group action.
Semisimple: In the context of algebraic groups, a semisimple group is a type of group that can be expressed as a direct product of simple groups, which are non-abelian groups that have no normal subgroups other than the trivial group and themselves. Semisimple groups are important because they exhibit certain structural properties that allow for a clearer understanding of their representations and actions, particularly when it comes to understanding how these groups interact with algebraic varieties.
Sl(n): The term sl(n) refers to the special linear group of degree n, which is the group of n x n matrices with determinant equal to 1. This group is important in the study of algebraic groups and group actions as it reflects symmetry and transformations in n-dimensional space, playing a key role in both geometry and representation theory.
Solvable group: A solvable group is a type of group in abstract algebra where the group can be broken down into simpler components through a series of normal subgroups. This means there is a sequence of subgroups where each is normal in the next one, and the factor groups formed from this sequence are abelian. Solvable groups have important connections to algebraic structures, especially in terms of understanding polynomial equations and their solutions through group theory.
Subgroup: A subgroup is a subset of a group that is itself a group under the same operation as the larger group. This means that a subgroup must include the identity element, be closed under the group operation, and contain the inverse for each of its elements. Subgroups are essential in understanding the structure of algebraic groups and how they act on various spaces.
Unipotent group: A unipotent group is an algebraic group where every element can be expressed as a unipotent matrix, meaning that all eigenvalues are equal to one. This type of group is significant because it has a simple structure that is easy to analyze, making it useful in various mathematical contexts, particularly in understanding the properties of algebraic groups and their actions. Unipotent groups often arise in the study of nilpotent Lie algebras and are crucial in the representation theory of algebraic groups.
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