Introduction To Lie algebras. Paniz Imani

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Transcription:

Introduction To Lie algebras Paniz Imani 1

Contents 1 Lie algebras 3 1.1 Definition and examples....................................... 3 1.2 Some Basic Notions......................................... 4 2 Free Lie Algebras 4 3 Representations 4 4 The Universal Enveloping Algebra 5 4.1 Constructing U(g).......................................... 5 5 Simple Lie algebras, Semisimple Lie algebras, Killing form, Cartan criterion for semisimplicity 6 2

1 Lie algebras 1.1 Definition and examples Definition 1.1. A Lie algebra is a vector space g over a field F with an operation [, ] : g g g which we call a Lie bracket, such that the following axioms are satisfied: It is bilinear. It is skew symmetric: [x, x] = 0 which implies [x, y] = [y, x] for all x, y g. It satisfies the Jacobi Identitiy: [x, [y, z]] + [y, [z, x]] + [z, [x, y]] = 0. Definition 1.2. A Lie algebra Homomorphism is a linear map H Hom(g, h)between to Lie algebras g and h such that it is compatible with the Lie bracket: H : g h and H([x, y]) = [H(x), H(y)] Example 1.1. Any vector space can be made into a Lie algebra with the trivial bracket: for all v, w V. [v, w] = 0 Example 1.2. Let g be a Lie algebra over a field F. We take any nonzero element x g and construct the space spanned by x, we denote it by F x. This is an abelian one dimentional Lie algebra: Let a, b F x. We compute the Lie bracket. [αx, βx] = αβ[x, x] = 0. where α, β F. Note: This shows in particular that all one dimentional Lie algebras have a trivial bracket. Example 1.3. Any associative algebra A can be made into a Lie algebra by taking commutator as the Lie bracket: [x, y] = xy yx for all x, y A. Example 1.4. Let V be any vector space. The space of End(V ) forms an associative algebra under function composition. It is also a Lie algebra with the commutator as the Lie bracket. Whenever we think of it as a Lie algebra we denote it by gl(v ). This is the General Linear Lie algebra. Example 1.5. Let V be a finite dimentional vector space over a field F. Then we identify the Lie algebra gl(v ) with set of n n matrices gl n (F), where n is the dimension of V. The set of all matrices with the trace zero sl n F is a subalgebra of gl n (F). Example 1.6. The set of anti symmetric matrices with the trace zero denoted by so n forms a Lie algebra under the commutator as the Lie bracket. Example 1.7. Heisenberg algebra: We look at the vector space H generated over F by the matrices: 0 1 0 0 0 1 0 0 0 0 0 0, 0 0 0, 0 0 1 0 0 0 0 0 0 0 0 0 This is a linear subspace of gl 3 (F ) and becomes a Lie algebra under the commutator bracket. The fact that H is closed under the commutator bracket follows from the well-known commutator identity on the standard basis of n n matrices: [E ij, E kl ] = δ jk E il δ li E kj where δ ij is the Kronecker delta. 3

1.2 Some Basic Notions Definition 1.3. Let g be a Lie algebra over F. Then a linear subspace U g is a Lie subalgebra if U is closed under the Lie bracket of g: [x, y] U for all x, y U. Definition 1.4. Let I be a linear subspace of a Lie algebra g. Then I is an ideal of g if whenever x I and y g. [x, y] I Definition 1.5. A Lie algebra g is called abelian if the Lie bracket vanishes for all elements in g: for all x, y g. [x, y] = 0 Definition 1.6. Let U be a non empty subset of g, we call U the Lie subalgebra (ideal) generated by U, where: U = {I g : I is Lie subalgebra (ideal) containing U} 2 Free Lie Algebras Let X be a set. We define W X = x X F,where F is an arbitrary field. Then we denote the tensor algebra of W X by T W X which is as well a Lie algebra. The Free Lie algebra on X is the Lie subalgebra in T W X generated by X. Where X can be canonically embedded into W X via the map: f : X W X. x e x 3 Representations A representation of a Lie algebra g is a Lie algebra homomorphism from g to the Lie algebra End(V ): ρ : g gl(v ). Definition 3.1. For a Lie algebra g and any x g we define a map ad x : g g, y [x, y] which is the adjoint action. Every Lie algebra has a representation on itself, the adjoint representation defined via the map: ad : g gl(g) x ad x. Definition 3.2. For two representations of a Lie algebra g, φ : g gl(v ) and φ : g gl(v ) a morphism from φ to φ is a linear map ψ : V V such that it is compatible with the action of g on V and V : φ (x)ψ = ψφ(x) For all x g. This constitutes the category g Mod. 4

4 The Universal Enveloping Algebra For any associative algebra we construct a Lie algebra by taking the commutator as the Lie bracket. Now let us think in the reverse direction. We want to see if we can construct an associative algebra from a given Lie algebra and its consequences. With this construction, instead of non-associative scructures;lie algebras, we can work with nicer and better developed structures: Unital associative algebras that captures the important properties of our Lie algebra. 4.1 Constructing U(g) Let us construct the tensor algebra of the Lie algebra g: T g = T k g = g... g }{{} k=0 k=0 k times We look at the two sided ideal I generated by : g h h g [g, h] For g, h T g. Its elements look like: k i=0 c i (x (i) 1... x(i) n i ) (g i h i h i g i [g i, h i ]) (y (i) 1... y (i) n i ) for g i, h i T g. Now the universal enveloping algebra is constructed by taking the quotient of our tensor algebra: U(g) = T (g)/i. Definition 4.1. For two ring homomorphisms S : U(g) End(W ) and S : U(g) End(W ) a morphism from S to S is a map t : W W such that it is compatible with the action of U(g) on W and W : This constitutes the category U(g) Mod. S (x)t = ts(x). Theorem 4.1. To each representation φ : g gl(v ) we can associate some S φ : U(g) End(V ) and to each ring homomorphism S : U(g) End(V ) we can associate some φ S : g gl(v ), such that a morphism ψ from φ to φ is also a morphism from S φ to S φ and a morphism t from S to S is also a morphism from φ s to φ S,and φ S φ = φ and S φs = S. Remark. This is equivalent as to say g-mod is equivalent to U(g)-Mod. Proof. Suppose we are given a representation φ, we want to construct S φ such that it will satisfy the properties of a ring homomorphism, that is: (1) S φ (1) = 1 (2) S φ (r + r ) = S(r) + S(r) (3) S φ (rr ) = S(r)S(r ) We define S φ as follows: S φ (1) = 1 So that (1) holds. We consider an element of x 1... x n U(g), we define S on x 1... x n : S φ (x 1... x n ) = φ(x 1 ) φ(x 2 )... φ(x n ). Now we define S on the rest of U(g) by linear extension: S φ (x 1...x n + y 1...y m ) = S φ (x 1...x n ) + S φ (y 1...y n ) 5

It is clear that (2) is also satisfied. We show that (3) is satisfied as well: S φ (x 1...x n y 1...y m ) = φ(x 1 )...φ(x n ) φ(y 1 )... φ(y m ) = S φ (x 1...x n ) S φ (y 1...y n ) Now suppose we have S and we want to define φ S : φ S (x) = S(x) we want to show that its a Lie algebra representation: φ S ([x, y]) = S(x y y x) = S(x y) S(y x) = S(x) S(y) S(y) S(x) = φ S (x) φ S (y) φ S (y) φ S (x) Now we will show if ψ is a morphism from φ to φ then it is also a morphism from S φ to S φ. By definition S φ = φ, Thus: S φ (x)ψ = ψ S(x). Taking another element x y U(g) Mod, we will have: S φ (x y)ψ = ψ S(x y) S (x) S (y) ψ = S (x) ψ S(y) = ψ s(x) S(y) = ψ S(x y) From the equation above it is obvious that this holds for any arbitrary element x 1... x n U(g). That is we have: S φ (x 1... x n )ψ = ψ S φ (x 1... x n ) The other way around to show that t is also a morphism from φ to φ is obvious by using the one to one correspondence between φ and s. The only thing left is to show that φ Sφ (x) = φ(x) and S φs (X) = S(x). For the first case we mean that if we start from φ go to φ S and then to φ Sφ we get the same φ. Let s look at the definition of φ Sφ. It is a Lie algebra representation that we get from the ring homomorphism S φ. by defining φ Sφ (x) := S φ (x), and we defined S φ (x) = φ(x). Therefore: φ Sφ (X) = φ(x). To show S φs (x) = S(x), we use the same trick. By definition: We insert the definition of φ S (x): S φs (x 1... x n ) = φ S (x 1 )... φ(x n ) φ S (x 1 )... φ S (x n ) = S(x 1 )... S(x n ) but since S is a ring homomorphism, we have that it is multiplicative: Therefore S φs (x) = S(x). S(x 1 ).. S(x n ) = S(x 1... x n ). 5 Simple Lie algebras, Semisimple Lie algebras, Killing form, Cartan criterion for semisimplicity Definition 5.1. A non abelian Lie algebra g is called simple if it has no non trivial ideals. Definition 5.2. We define a Lie algebra g to be semisimple if it is the finite direct sum of simple Lie algebras g i : g = g 1 g 2... g n. 6

Definition 5.3. Let g be a finite dimentional Lie algebra over a field F. The Killing form κ is the bilinear form κ : g g F defined by κ(x, y) = T r(ad x ad y ) x, y, z g. It has the following properties: It is bilinear. It is symmetric. It is ad invariant:. κ([y, x], z) + κ(x, [y, z]) = 0 Definition 5.4. The Killing form is said to be non degenerate if: y = 0 κ(x, y) = 0 implies x = 0. Theorem 5.1. Cartan criterion: A Lie algebra g over a field F of characteristic zero is semisimple if and only if the Killing form is non degenerate. 7

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