Representation Theory

🧩Representation Theory Unit 10 – Introduction to Lie Algebras

Lie algebras are vector spaces with a special operation called the Lie bracket. They capture the local structure of Lie groups and play a crucial role in studying symmetries in mathematics and physics. Lie algebras have applications in quantum mechanics, differential geometry, and algebraic topology. Key concepts include the Lie bracket, subalgebras, ideals, and simple and semisimple Lie algebras. The classification of simple Lie algebras over complex numbers is a major achievement. Representation theory of Lie algebras is essential for understanding their structure and applications.

Study Guides for Unit 10

10.1

Definition and basic properties of Lie algebras

2 min read

10.2

Classical Lie algebras and their classification

3 min read

10.3

Structure theory of Lie algebras

2 min read

Key Concepts and Definitions

Lie algebra defined as a vector space $V$ over a field $F$ with a bilinear operation called the Lie bracket $[x, y]$ satisfying antisymmetry and the Jacobi identity
Lie bracket operation $[x, y]$ measures the extent to which the multiplication in a Lie group fails to be commutative near the identity element
Dimension of a Lie algebra is its dimension as a vector space over its base field
Abelian Lie algebra has a Lie bracket that always vanishes, i.e., $[x, y] = 0$ for all elements $x$ and $y$
Subalgebra is a vector subspace that is closed under the Lie bracket operation
- Proper subalgebra is a subalgebra that is strictly smaller than the whole Lie algebra
Ideal is a subalgebra $I$ satisfying $[x, y] \in I$ for all $x \in I$ and $y \in V$
Simple Lie algebra contains no non-trivial ideals and is not abelian
Semisimple Lie algebra is a direct sum of simple Lie algebras
Nilpotent Lie algebra has a central series that terminates in zero
- Lower central series defined by $L_1 = L$ and $L_{i+1} = [L, L_i]$

Historical Context and Motivation

Sophus Lie introduced Lie algebras in the late 19th century to study symmetries of differential equations
Lie algebras capture the local structure of Lie groups near the identity element
Infinitesimal approach to studying Lie groups by linearizing the group operation
Representation theory of Lie algebras used to construct representations of Lie groups
Lie algebras play a crucial role in various areas of mathematics and physics
- Symmetries in quantum mechanics and particle physics
- Differential geometry and topology
- Integrable systems and mathematical physics
Classification of simple Lie algebras over $\mathbb{C}$ by Killing and Cartan in the late 19th and early 20th centuries
Real forms of complex Lie algebras studied by Élie Cartan

Fundamental Properties of Lie Algebras

Antisymmetry of the Lie bracket: $[x, y] = -[y, x]$ for all elements $x$ and $y$
Jacobi identity: $[x, [y, z]] + [y, [z, x]] + [z, [x, y]] = 0$ for all elements $x$ , $y$ , and $z$
Bilinearity of the Lie bracket over the base field $F$ $F$
- $[ax + by, z] = a[x, z] + b[y, z]$ for all $a, b \in F$ and $x, y, z \in V$
- $[x, ay + bz] = a[x, y] + b[x, z]$ for all $a, b \in F$ and $x, y, z \in V$
Adjoint representation $\text{ad}_x: V \to V$ defined by $\text{ad}_x(y) = [x, y]$ is a derivation of the Lie algebra
Engel's theorem states that a Lie algebra is nilpotent if and only if $\text{ad}_x$ is nilpotent for all $x \in V$
Derived series of a Lie algebra defined by $L^{(0)} = L$ $L^{(0)} = L$ and $L^{(i+1)} = [L^{(i)}, L^{(i)}]$ $L^{(i + 1)} = [L^{(i)}, L^{(i)}]$
- Lie algebra is solvable if its derived series terminates in zero

Classification of Simple Lie Algebras

Killing-Cartan classification of simple Lie algebras over $\mathbb{C}$ $C$
- Four infinite families: $A_n$ ( $n \geq 1$ ), $B_n$ ( $n \geq 2$ ), $C_n$ ( $n \geq 3$ ), and $D_n$ ( $n \geq 4$ )
- Five exceptional cases: $G_2$ , $F_4$ , $E_6$ , $E_7$ , and $E_8$
Each simple Lie algebra corresponds to a connected and simply-connected simple Lie group
Dynkin diagrams encode the structure of simple Lie algebras
- Nodes represent simple roots and edges represent angles between them
Weyl group is the reflection group generated by reflections in the hyperplanes orthogonal to the roots
Cartan matrix encodes the angles between simple roots and determines the Lie algebra up to isomorphism
Real forms of complex simple Lie algebras classified using Satake diagrams and Vogan diagrams

Representation Theory Basics for Lie Algebras

Representation of a Lie algebra $L$ $L$ is a vector space $V$ $V$ together with a Lie algebra homomorphism $\rho: L \to \mathfrak{gl}(V)$ $ρ : L \to gl (V)$
- $\rho([x, y]) = [\rho(x), \rho(y)]$ for all $x, y \in L$
Irreducible representation has no non-trivial invariant subspaces
Completely reducible representation decomposes into a direct sum of irreducible representations
Adjoint representation $\text{ad}: L \to \mathfrak{gl}(L)$ defined by $\text{ad}_x(y) = [x, y]$ is a representation of $L$
Weights are eigenvalues of the action of a Cartan subalgebra on a representation
- Weight space is the eigenspace corresponding to a weight
Highest weight theory classifies irreducible representations of semisimple Lie algebras
- Highest weight vector is annihilated by the action of positive root spaces
- Irreducible representation generated by a highest weight vector

Important Examples and Applications

$\mathfrak{sl}_n(\mathbb{C})$ $sl_{n} (C)$ , the special linear Lie algebra, consists of $n \times n$ $n \times n$ matrices with trace zero
- Corresponds to the special linear group $SL_n(\mathbb{C})$
$\mathfrak{so}_n(\mathbb{R})$ $so_{n} (R)$ , the special orthogonal Lie algebra, consists of skew-symmetric $n \times n$ $n \times n$ matrices
- Corresponds to the special orthogonal group $SO(n)$
$\mathfrak{su}_n$ $su_{n}$ , the special unitary Lie algebra, consists of skew-Hermitian $n \times n$ $n \times n$ matrices with trace zero
- Corresponds to the special unitary group $SU(n)$
Heisenberg Lie algebra is a nilpotent Lie algebra with basis $\{x, y, z\}$ and non-zero brackets $[x, y] = z$
Virasoro algebra is an infinite-dimensional Lie algebra important in conformal field theory and string theory
Kac-Moody algebras are infinite-dimensional generalizations of semisimple Lie algebras
- Affine Lie algebras are a special case related to loop groups and central extensions

Computational Techniques and Exercises

Computation of Lie brackets using the antisymmetry and bilinearity properties
Verifying the Jacobi identity for specific examples of Lie algebras
Finding subalgebras and ideals of given Lie algebras
Determining the derived series and lower central series of Lie algebras
Classifying low-dimensional Lie algebras up to isomorphism
Computing the Killing form and Cartan matrix for simple Lie algebras
Constructing irreducible representations using highest weight theory
Decomposing representations into irreducible components
Calculating weights and weight spaces for representations of Lie algebras
Exploring the structure of root systems and Weyl groups

Connections to Other Mathematical Fields

Relationship between Lie algebras and Lie groups via the exponential map
- Baker-Campbell-Hausdorff formula expresses the group operation in terms of Lie brackets
Lie algebra cohomology and its applications in representation theory and geometry
Poisson algebras as a generalization of Lie algebras with a compatible associative multiplication
Quantum groups as deformations of universal enveloping algebras of Lie algebras
Lie algebroids as a generalization of Lie algebras with a vector bundle structure
- Lie groupoids integrate Lie algebroids analogously to Lie groups integrating Lie algebras
Representation theory of Lie algebras applied to physics
- Symmetries in quantum mechanics and particle physics
- Gauge theories and Yang-Mills equations
Connections to algebraic geometry through the study of algebraic groups and their Lie algebras
Relationship to differential geometry via Lie algebra valued differential forms and connections