In mathematics, particularly in the theory of spinors, the Weyl–Brauer matrices are an explicit realization of a Clifford algebra as a matrix algebra of matrices. They generalize the Pauli matrices to dimensions, and are a specific construction of higher-dimensional gamma matrices. They are named for Richard Brauer and Hermann Weyl,[1] and were one of the earliest systematic constructions of spinors from a representation theoretic standpoint.
The matrices are formed by taking tensor products of the Pauli matrices, and the space of spinors in dimensions may then be realized as the column vectors of size on which the Weyl–Brauer matrices act.
Suppose that V = Rn is a Euclidean space of dimension n. There is a sharp contrast in the construction of the Weyl–Brauer matrices depending on whether the dimension n is even or odd.
Let = 2 (or 2+1) and suppose that the Euclidean quadratic form on is given by
| 2 | |
| q | |
| k |
~~
| 2)~, | |
| (+p | |
| n |
Define matrices 1, 1', P, and Q by
\begin{matrix} {1}=\sigma0=\left(\begin{matrix}1&0\\0&1\end{matrix}\right),& {1}'=\sigma3=\left(\begin{matrix}1&0\\0&-1\end{matrix}\right),\\ P=\sigma1=\left(\begin{matrix}0&1\\1&0\end{matrix}\right),& Q=-\sigma2=\left(\begin{matrix}0&i\\-i&0\end{matrix}\right) \end{matrix}
In even or in odd dimensionality, this quantization procedure amounts to replacing the ordinary p, q coordinates with non-commutative coordinates constructed from P, Q in a suitable fashion.
In the case when n = 2k is even, let
Pi={1}' ⊗ ... ⊗ {1}' ⊗ P ⊗ {1} ⊗ ... ⊗ {1}
Qi={1}' ⊗ ... ⊗ {1}' ⊗ Q ⊗ {1} ⊗ ... ⊗ {1}
⊗
| 2 | |
| P | |
| i |
=1,i=1,2,...,2k
PiPj=-PjPi
Let A denote the algebra generated by these matrices. By counting dimensions, A is a complete 2k×2k matrix algebra over the complex numbers. As a matrix algebra, therefore, it acts on 2k-dimensional column vectors (with complex entries). These column vectors are the spinors.
We now turn to the action of the orthogonal group on the spinors. Consider the application of an orthogonal transformation to the coordinates, which in turn acts upon the Pi via
Pi\mapstoR(P)i=\sumjRijPj
That is,
R\inSO(n)
R(P)i=
| -1 | |
| S(R)P | |
| iS(R) |
There is more than one matrix S(R) which produces the action in (1). The ambiguity defines S(R) up to a nonevanescent scalar factor c. Since S(R) and cS(R) define the same transformation (1), the action of the orthogonal group on spinors is not single-valued, but instead descends to an action on the projective space associated to the space of spinors. This multiple-valued action can be sharpened by normalizing the constant c in such a way that (det S(R))2 = 1. In order to do this, however, it is necessary to discuss how the space of spinors (column vectors) may be identified with its dual (row vectors).
In order to identify spinors with their duals, let C be the matrix defined by
C=P ⊗ Q ⊗ P ⊗ ... ⊗ Q.
\hbox{
| tP | |
| } | |
| i → |
tS(R)-1
| tS(R) | |
| i |
=(CS(R)C-1
| -1 | |
| ) | |
| i(CS(R)C |
)-1
In physics, the matrix C is conventionally interpreted as charge conjugation.
Let U be the element of the algebra A defined by
U={1}' ⊗ ... ⊗ {1}'
ξ = ξ+ + ξ−into a right-handed Weyl spinor ξ+ and a left-handed Weyl spinor ξ−. Because rotations preserve the eigenspaces of U, the rotations themselves act diagonally as matrices S(R)+, S(R)− via
(S(R)ξ)+ = S+(R) ξ+, and
(S(R)ξ)− = S−(R) ξ−.
This decomposition is not, however, stable under improper rotations (e.g., reflections in a hyperplane). A reflection in a hyperplane has the effect of interchanging the two eigenspaces. Thus there are two irreducible spin representations in even dimensions given by the left-handed and right-handed Weyl spinors, each of which has dimension 2k-1. However, there is only one irreducible pin representation (see below) owing to the non-invariance of the above eigenspace decomposition under improper rotations, and that has dimension 2k.
In the quantization for an odd number 2k+1 of dimensions, the matrices Pi may be introduced as above for i = 1,2,...,2k, and the following matrix may be adjoined to the system:
Pn={1}' ⊗ ... ⊗ {1}'
Nevertheless, one can show that if R is a proper rotation (an orthogonal transformation of determinant one), then the rotation among the coordinates
R(P)i=\sumjRijPj
is again an automorphism of A, and so induces a change of basis
R(P)i=
| -1 | |
| S(R)P | |
| iS(R) |
In the case of odd dimensions it is not possible to split a spinor into a pair of Weyl spinors, and spinors form an irreducible representation of the spin group. As in the even case, it is possible to identify spinors with their duals, but for one caveat. The identification of the space of spinors with its dual space is invariant under proper rotations, and so the two spaces are spinorially equivalent. However, if improper rotations are also taken into consideration, then the spin space and its dual are not isomorphic. Thus, while there is only one spin representation in odd dimensions, there are a pair of inequivalent pin representations. This fact is not evident from the Weyl's quantization approach, however, and is more easily seen by considering the representations of the full Clifford algebra.