Matrix Lie algebras A
matrix group is a Lie group consisting of invertible matrices, G\subset \mathrm{GL}(n,\mathbb{R}), where the group operation of
G is matrix multiplication. The corresponding Lie algebra \mathfrak g is the space of matrices which are tangent vectors to
G inside the linear space M_n(\mathbb{R}): this consists of derivatives of smooth curves in
G at the
identity matrix I: :\mathfrak{g} = \{ X = c'(0) \in M_n(\mathbb{R}) : \text{ smooth } c: \mathbb{R}\to G, \ c(0) = I \}. The Lie bracket of \mathfrak{g} is given by the commutator of matrices, [X,Y]=XY-YX. Given a Lie algebra \mathfrak{g}\subset \mathfrak{gl}(n,\mathbb{R}), one can recover the Lie group as the subgroup generated by the
matrix exponential of elements of \mathfrak{g}. (To be precise, this gives the
identity component of
G, if
G is not connected.) Here the exponential mapping \exp: M_n(\mathbb{R})\to M_n(\mathbb{R}) is defined by \exp(X) = I + X + \tfrac{1}{2!}X^2 + \tfrac{1}{3!}X^3 + \cdots, which converges for every matrix X. The same comments apply to complex Lie subgroups of GL(n,\mathbb{C}) and the complex matrix exponential, \exp: M_n(\mathbb{C})\to M_n(\mathbb{C}) (defined by the same formula). Here are some matrix Lie groups and their Lie algebras. • For a positive integer
n, the
special linear group \mathrm{SL}(n,\mathbb{R}) consists of all real matrices with determinant 1. This is the group of linear maps from \mathbb{R}^n to itself that preserve volume and
orientation. More abstractly, \mathrm{SL}(n,\mathbb{R}) is the
commutator subgroup of the general linear group \mathrm{GL}(n,\R). Its Lie algebra \mathfrak{sl}(n,\mathbb{R}) consists of all real matrices with
trace 0. Similarly, one can define the analogous complex Lie group {\rm SL}(n,\mathbb{C}) and its Lie algebra \mathfrak{sl}(n,\mathbb{C}). • The
orthogonal group \mathrm{O}(n) plays a basic role in geometry: it is the group of linear maps from \mathbb{R}^n to itself that preserve the length of vectors. For example, rotations and reflections belong to \mathrm{O}(n). Equivalently, this is the group of
n x
n orthogonal matrices, meaning that A^{\mathrm{T}}=A^{-1}, where A^{\mathrm{T}} denotes the
transpose of a matrix. The orthogonal group has two connected components; the identity component is called the
special orthogonal group \mathrm{SO}(n), consisting of the orthogonal matrices with determinant 1. Both groups have the same Lie algebra \mathfrak{so}(n), the subspace of skew-symmetric matrices in \mathfrak{gl}(n,\mathbb{R}) (X^{\rm T}=-X). See also
infinitesimal rotations with skew-symmetric matrices. :The complex orthogonal group \mathrm{O}(n,\mathbb{C}), its identity component \mathrm{SO}(n,\mathbb{C}), and the Lie algebra \mathfrak{so}(n,\mathbb{C}) are given by the same formulas applied to
n x
n complex matrices. Equivalently, \mathrm{O}(n,\mathbb{C}) is the subgroup of \mathrm{GL}(n,\mathbb{C}) that preserves the standard
symmetric bilinear form on \mathbb{C}^n. • The
unitary group \mathrm{U}(n) is the subgroup of \mathrm{GL}(n,\mathbb{C}) that preserves the length of vectors in \mathbb{C}^n (with respect to the standard
Hermitian inner product). Equivalently, this is the group of
n ×
n unitary matrices (satisfying A^*=A^{-1}, where A^* denotes the
conjugate transpose of a matrix). Its Lie algebra \mathfrak{u}(n) consists of the skew-hermitian matrices in \mathfrak{gl}(n,\mathbb{C}) (X^*=-X). This is a Lie algebra over \mathbb{R}, not over \mathbb{C}. (Indeed,
i times a skew-hermitian matrix is hermitian, rather than skew-hermitian.) Likewise, the unitary group \mathrm{U}(n) is a real Lie subgroup of the complex Lie group \mathrm{GL}(n,\mathbb{C}). For example, \mathrm{U}(1) is the
circle group, and its Lie algebra (from this point of view) is i\mathbb{R}\subset \mathbb{C}=\mathfrak{gl}(1,\mathbb{C}). • The
special unitary group \mathrm{SU}(n) is the subgroup of matrices with determinant 1 in \mathrm{U}(n). Its Lie algebra \mathfrak{su}(n) consists of the skew-hermitian matrices with trace zero. • The
symplectic group \mathrm{Sp}(2n,\R) is the subgroup of \mathrm{GL}(2n,\mathbb{R}) that preserves the standard
alternating bilinear form on \mathbb{R}^{2n}. Its Lie algebra is the
symplectic Lie algebra \mathfrak{sp}(2n,\mathbb{R}). • The
classical Lie algebras are those listed above, along with variants over any field.
Two dimensions Some Lie algebras of low dimension are described here. See the
classification of low-dimensional real Lie algebras for further examples. • There is a unique nonabelian Lie algebra \mathfrak{g} of dimension 2 over any field
F, up to isomorphism. Here \mathfrak{g} has a basis X,Y for which the bracket is given by \left [X, Y\right ] = Y. (This determines the Lie bracket completely, because the axioms imply that [X,X]=0 and [Y,Y]=0.) Over the real numbers, \mathfrak{g} can be viewed as the Lie algebra of the Lie group G=\mathrm{Aff}(1,\mathbb{R}) of
affine transformations of the real line, x\mapsto ax+b. :The affine group
G can be identified with the group of matrices :: \left( \begin{array}{cc} a & b\\ 0 & 1 \end{array} \right) :under matrix multiplication, with a,b \in \mathbb{R} , a \neq 0. Its Lie algebra is the Lie subalgebra \mathfrak{g} of \mathfrak{gl}(2,\mathbb{R}) consisting of all matrices :: \left( \begin{array}{cc} c & d\\ 0 & 0 \end{array}\right). :In these terms, the basis above for \mathfrak{g} is given by the matrices :: X= \left( \begin{array}{cc} 1 & 0\\ 0 & 0 \end{array}\right), \qquad Y= \left( \begin{array}{cc} 0 & 1\\ 0 & 0 \end{array}\right). :For any field F, the 1-dimensional subspace F\cdot Y is an ideal in the 2-dimensional Lie algebra \mathfrak{g}, by the formula [X,Y]=Y\in F\cdot Y. Both of the Lie algebras F\cdot Y and \mathfrak{g}/(F\cdot Y) are abelian (because 1-dimensional). In this sense, \mathfrak{g} can be broken into abelian "pieces", meaning that it is solvable (though not nilpotent), in the terminology below.
Three dimensions • The
Heisenberg algebra \mathfrak{h}_3(F) over a field
F is the three-dimensional Lie algebra with a basis X,Y,Z such that ::[X,Y] = Z,\quad [X,Z] = 0, \quad [Y,Z] = 0. :It can be viewed as the Lie algebra of 3×3 strictly
upper-triangular matrices, with the commutator Lie bracket and the basis :: X = \left( \begin{array}{ccc} 0&1&0\\ 0&0&0\\ 0&0&0 \end{array}\right),\quad Y = \left( \begin{array}{ccc} 0&0&0\\ 0&0&1\\ 0&0&0 \end{array}\right),\quad Z = \left( \begin{array}{ccc} 0&0&1\\ 0&0&0\\ 0&0&0 \end{array}\right)~.\quad :Over the real numbers, \mathfrak{h}_3(\mathbb{R}) is the Lie algebra of the
Heisenberg group \mathrm{H}_3(\mathbb{R}), that is, the group of matrices ::\left( \begin{array}{ccc} 1&a&c\\ 0&1&b\\ 0&0&1 \end{array}\right) :under matrix multiplication. :For any field
F, the center of \mathfrak{h}_3(F) is the 1-dimensional ideal F\cdot Z, and the quotient \mathfrak{h}_3(F)/(F\cdot Z) is abelian, isomorphic to F^2. In the terminology below, it follows that \mathfrak{h}_3(F) is nilpotent (though not abelian). • The Lie algebra \mathfrak{so}(3) of the
rotation group SO(3) is the space of skew-symmetric 3 x 3 matrices over \mathbb{R}. A basis is given by the three matrices :: F_1 = \left( \begin{array}{ccc} 0&0&0\\ 0&0&-1\\ 0&1&0 \end{array}\right),\quad F_2 = \left( \begin{array}{ccc} 0&0&1\\ 0&0&0\\ -1&0&0 \end{array}\right),\quad F_3 = \left( \begin{array}{ccc} 0&-1&0\\ 1&0&0\\ 0&0&0 \end{array}\right)~.\quad :The commutation relations among these generators are ::[F_1, F_2] = F_3, ::[F_2, F_3] = F_1, ::[F_3, F_1] = F_2. :The cross product of vectors in \mathbb{R}^3 is given by the same formula in terms of the standard basis; so that Lie algebra is isomorphic to \mathfrak{so}(3). Also, \mathfrak{so}(3) is equivalent to the
Spin (physics) angular-momentum component operators for spin-1 particles in
quantum mechanics. :The Lie algebra \mathfrak{so}(3) cannot be broken into pieces in the way that the previous examples can: it is
simple, meaning that it is not abelian and its only ideals are 0 and all of \mathfrak{so}(3). • Another simple Lie algebra of dimension 3, in this case over \mathbb{C}, is the space \mathfrak{sl}(2,\mathbb{C}) of 2 x 2 matrices of trace zero. A basis is given by the three matrices :H= \left( \begin{array}{cc} 1 & 0\\ 0 & -1 \end{array} \right),\ E =\left ( \begin{array}{cc} 0 & 1\\ 0 & 0 \end{array} \right),\ F =\left( \begin{array}{cc} 0 & 0\\ 1 & 0 \end{array} \right). {{multiple image | width = 220 | footer = The action of \mathfrak{sl}(2,\mathbb{C}) on the
Riemann sphere \mathbb{CP}^1. In particular, the Lie brackets of the vector fields shown are: [H,E]=2E, [H,F]=-2F, [E,F]=H. | image1 = Vector field H.png | alt1 = Vector field H | caption1 = H | image2 = Vector field E.png | alt2 = Vector field E | caption2 = E | image3 = Vector field F.png | alt3 = Vector field F | caption3 = F }} :The Lie bracket is given by: ::[H, E] = 2E, ::[H, F] = -2F, ::[E, F] = H. :Using these formulas, one can show that the Lie algebra \mathfrak{sl}(2,\mathbb{C}) is simple, and classify its finite-dimensional representations (defined below). In the terminology of quantum mechanics, one can think of
E and
F as
raising and lowering operators. Indeed, for any representation of \mathfrak{sl}(2,\mathbb{C}), the relations above imply that
E maps the
c-
eigenspace of
H (for a complex number
c) into the (c+2)-eigenspace, while
F maps the
c-eigenspace into the (c-2)-eigenspace. :The Lie algebra \mathfrak{sl}(2,\mathbb{C}) is isomorphic to the
complexification of \mathfrak{so}(3), meaning the
tensor product \mathfrak{so}(3)\otimes_{\mathbb{R}}\mathbb{C}. The formulas for the Lie bracket are easier to analyze in the case of \mathfrak{sl}(2,\mathbb{C}). As a result, it is common to analyze complex representations of the group \mathrm{SO}(3) by relating them to representations of the Lie algebra \mathfrak{sl}(2,\mathbb{C}).
Infinite dimensions • The Lie algebra of vector fields on a smooth manifold of positive dimension is an infinite-dimensional Lie algebra over \mathbb{R}. • The
Kac–Moody algebras are a large class of infinite-dimensional Lie algebras, say over \mathbb{C}, with structure much like that of the finite-dimensional simple Lie algebras (such as \mathfrak{sl}(n,\C)). • The
Moyal algebra is an infinite-dimensional Lie algebra that contains all the
classical Lie algebras as subalgebras. • The
Virasoro algebra is important in
string theory. • The functor that takes a Lie algebra over a field
F to the underlying vector space has a
left adjoint V\mapsto L(V), called the
free Lie algebra on a vector space
V. It is spanned by all iterated Lie brackets of elements of
V, modulo only the relations coming from the definition of a Lie algebra. The free Lie algebra L(V) is infinite-dimensional for
V of dimension at least 2. == Representations ==