Gamma matrices

In mathematical physics, the gamma matrices, ${\displaystyle \left\{\gamma ^{0},\gamma ^{1},\gamma ^{2},\gamma ^{3}\right\}}$, also known as the Dirac matrices, are a set of conventional matrices with specific anticommutation relations that ensure they generate a matrix representation of the Clifford algebra Cl_1,3(R). It is also possible to define higher-dimensional gamma matrices. When interpreted as the matrices of the action of a set of orthogonal basis vectors for contravariant vectors in Minkowski space, the column vectors on which the matrices act become a space of spinors, on which the Clifford algebra of spacetime acts. This in turn makes it possible to represent infinitesimal spatial rotations and Lorentz boosts. Spinors facilitate spacetime computations in general, and in particular are fundamental to the Dirac equation for relativistic spin-½ particles.

In Dirac representation, the four contravariant gamma matrices are

${\displaystyle {\begin{aligned}\gamma ^{0}&={\begin{pmatrix}1&0&0&0\\0&1&0&0\\0&0&-1&0\\0&0&0&-1\end{pmatrix}},&\gamma ^{1}&={\begin{pmatrix}0&0&0&1\\0&0&1&0\\0&-1&0&0\\-1&0&0&0\end{pmatrix}},\\\\\gamma ^{2}&={\begin{pmatrix}0&0&0&-i\\0&0&i&0\\0&i&0&0\\-i&0&0&0\end{pmatrix}},&\gamma ^{3}&={\begin{pmatrix}0&0&1&0\\0&0&0&-1\\-1&0&0&0\\0&1&0&0\end{pmatrix}}.\end{aligned}}}$

${\displaystyle \gamma ^{0}}$ is the time-like, hermitian matrix. The other three are space-like, antihermitian matrices. More compactly, ${\displaystyle \gamma ^{0}=\sigma ^{3}\otimes I}$, and ${\displaystyle \gamma ^{j}=i\sigma ^{2}\otimes \sigma ^{j}}$, where ${\displaystyle \otimes }$ denotes the Kronecker product and the ${\displaystyle \sigma ^{j}}$ (for j = 1, 2, 3) denote the Pauli matrices.

The gamma matrices have a group structure, the gamma group, that is shared by all matrix representations of the group, in any dimension, for any signature of the metric. For example, the Pauli matrices are a set of "gamma" matrices in dimension 3 with metric of Euclidean signature (3, 0). In 5 spacetime dimensions, the 4 gammas above together with the fifth gamma-matrix to be presented below generate the Clifford algebra.

Mathematical structure[]

The defining property for the gamma matrices to generate a Clifford algebra is the anticommutation relation

${\displaystyle \left\{\gamma ^{\mu },\gamma ^{\nu }\right\}=\gamma ^{\mu }\gamma ^{\nu }+\gamma ^{\nu }\gamma ^{\mu }=2\eta ^{\mu \nu }I_{4},}$

where ${\displaystyle \{,\}}$ is the anticommutator, ${\displaystyle \eta ^{\mu \nu }}$ is the Minkowski metric with signature (+ − − −), and ${\displaystyle I_{4}}$ is the 4 × 4 identity matrix.

This defining property is more fundamental than the numerical values used in the specific representation of the gamma matrices. Covariant gamma matrices are defined by

${\displaystyle \gamma _{\mu }=\eta _{\mu \nu }\gamma ^{\nu }=\left\{\gamma ^{0},-\gamma ^{1},-\gamma ^{2},-\gamma ^{3}\right\},}$

and Einstein notation is assumed.

Note that the other sign convention for the metric, (− + + +) necessitates either a change in the defining equation:

${\displaystyle \left\{\gamma ^{\mu },\gamma ^{\nu }\right\}=-2\eta ^{\mu \nu }I_{4}}$

or a multiplication of all gamma matrices by ${\displaystyle i}$, which of course changes their hermiticity properties detailed below. Under the alternative sign convention for the metric the covariant gamma matrices are then defined by

${\displaystyle \gamma _{\mu }=\eta _{\mu \nu }\gamma ^{\nu }=\left\{-\gamma ^{0},+\gamma ^{1},+\gamma ^{2},+\gamma ^{3}\right\}.}$

Physical structure[]

The Clifford algebra Cl_1,3(ℝ) over spacetime V can be regarded as the set of real linear operators from V to itself, End(V), or more generally, when complexified to Cl_1,3(ℝ)_ℂ, as the set of linear operators from any 4-dimensional complex vector space to itself. More simply, given a basis for V, Cl_1,3(ℝ)_ℂ is just the set of all 4 × 4 complex matrices, but endowed with a Clifford algebra structure. Spacetime is assumed to be endowed with the Minkowski metric η_μν. A space of bispinors, U_x, is also assumed at every point in spacetime, endowed with the bispinor representation of the Lorentz group. The bispinor fields Ψ of the Dirac equations, evaluated at any point x in spacetime, are elements of U_x, see below. The Clifford algebra is assumed to act on U_x as well (by matrix multiplication with column vectors Ψ(x) in U_x for all x). This will be the primary view of elements of Cl_1,3(ℝ)_ℂ in this section.

For each linear transformation S of U_x, there is a transformation of End(U_x) given by SES⁻¹ for E in Cl_1,3(ℝ)_ℂ ≈ End(U_x). If S belongs to a representation of the Lorentz group, then the induced action E ↦ SES⁻¹ will also belong to a representation of the Lorentz group, see Representation theory of the Lorentz group.

If S(Λ) is the bispinor representation acting on U_x of an arbitrary Lorentz transformation Λ in the standard (4-vector) representation acting on V, then there is a corresponding operator on End(U_x) = Cl_1,3(ℝ)_ℂ given by

${\displaystyle \gamma ^{\mu }\mapsto S(\Lambda )\gamma ^{\mu }S(\Lambda )^{-1}={\left(\Lambda ^{-1}\right)^{\mu }}_{\nu }\gamma ^{\nu }={\Lambda _{\nu }}^{\mu }\gamma ^{\nu },}$

showing that the γ^μ can be viewed as a basis of a representation space of the 4-vector representation of the Lorentz group sitting inside the Clifford algebra. The last identity can be recognized as the defining relationship for matrices belonging to an indefinite orthogonal group, which is ${\displaystyle \eta \Lambda ^{\textsf {T}}\eta =\Lambda ^{-1},}$ written in indexed notation. This means that quantities of the form

${\displaystyle a\!\!\!/:=a_{\mu }\gamma ^{\mu }}$

should be treated as 4-vectors in manipulations. It also means that indices can be raised and lowered on the γ using the metric η_μν as with any 4-vector. The notation is called the Feynman slash notation. The slash operation maps the basis e_μ of V, or any 4-dimensional vector space, to basis vectors γ_μ. The transformation rule for slashed quantities is simply

${\displaystyle {a\!\!\!/}^{\mu }\mapsto {\Lambda ^{\mu }}_{\nu }{a\!\!\!/}^{\nu }.}$

One should note that this is different from the transformation rule for the γ^μ, which are now treated as (fixed) basis vectors. The designation of the 4-tuple (γ^μ) = (γ⁰, γ¹, γ², γ³) as a 4-vector sometimes found in the literature is thus a slight misnomer. The latter transformation corresponds to an active transformation of the components of a slashed quantity in terms of the basis γ^μ, and the former to a passive transformation of the basis γ^μ itself.

The elements σ^μν = γ^μγ^ν − γ^νγ^μ form a representation of the Lie algebra of the Lorentz group. This is a spin representation. When these matrices, and linear combinations of them, are exponentiated, they are bispinor representations of the Lorentz group, e.g., the S(Λ) of above are of this form. The 6-dimensional space the σ^μν span is the representation space of a tensor representation of the Lorentz group. For the higher order elements of the Clifford algebra in general and their transformation rules, see the article Dirac algebra. The spin representation of the Lorentz group is encoded in the spin group Spin(1, 3) (for real, uncharged spinors) and in the complexified spin group Spin(1, 3) for charged (Dirac) spinors.

Expressing the Dirac equation[]

In natural units, the Dirac equation may be written as

${\displaystyle \left(i\gamma ^{\mu }\partial _{\mu }-m\right)\psi =0}$

where ${\displaystyle \psi }$ is a Dirac spinor.

Switching to Feynman notation, the Dirac equation is

${\displaystyle (i{\partial \!\!\!/}-m)\psi =0.}$

The fifth "gamma" matrix, γ⁵[]

It is useful to define a product of the four gamma matrices as ${\displaystyle \gamma ^{5}=\sigma _{1}\otimes I}$, so that

${\displaystyle \gamma ^{5}:=i\gamma ^{0}\gamma ^{1}\gamma ^{2}\gamma ^{3}={\begin{pmatrix}0&0&1&0\\0&0&0&1\\1&0&0&0\\0&1&0&0\end{pmatrix}}}$ (in the Dirac basis).

Although ${\displaystyle \gamma ^{5}}$ uses the letter gamma, it is not one of the gamma matrices of Cl_1,3(R). The number 5 is a relic of old notation in which ${\displaystyle \gamma ^{0}}$ was called "${\displaystyle \gamma ^{4}}$".

${\displaystyle \gamma ^{5}}$ has also an alternative form:

${\displaystyle \gamma ^{5}={\frac {i}{4!}}\varepsilon ^{\mu \nu \alpha \beta }\gamma _{\mu }\gamma _{\nu }\gamma _{\alpha }\gamma _{\beta }}$

using the convention ${\displaystyle \varepsilon _{0123}=1}$, or

${\displaystyle \gamma ^{5}=-{\frac {i}{4!}}\varepsilon ^{\mu \nu \alpha \beta }\gamma _{\mu }\gamma _{\nu }\gamma _{\alpha }\gamma _{\beta }}$

using the convention ${\displaystyle \varepsilon ^{0123}=1}$. Proof:

This can be seen by exploiting the fact that all the four gamma matrices anticommute, so

${\displaystyle \gamma ^{0}\gamma ^{1}\gamma ^{2}\gamma ^{3}=\gamma ^{[0}\gamma ^{1}\gamma ^{2}\gamma ^{3]}={\frac {1}{4!}}\delta _{\mu \nu \varrho \sigma }^{0123}\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\varrho }\gamma ^{\sigma }}$,

where ${\displaystyle \delta _{\mu \nu \varrho \sigma }^{\alpha \beta \gamma \delta }}$ is the type (4,4) generalized Kronecker delta in 4 dimensions, in full antisymmetrization. If ${\displaystyle \varepsilon _{\alpha \dots \beta }}$ denotes the Levi-Civita symbol in n dimensions, we can use the identity ${\displaystyle \delta _{\mu \nu \varrho \sigma }^{\alpha \beta \gamma \delta }=\varepsilon ^{\alpha \beta \gamma \delta }\varepsilon _{\mu \nu \varrho \sigma }}$. Then we get, using the convention ${\displaystyle \varepsilon ^{0123}=1}$,

${\displaystyle \gamma ^{5}=i\gamma ^{0}\gamma ^{1}\gamma ^{2}\gamma ^{3}={\frac {i}{4!}}\varepsilon ^{0123}\varepsilon _{\mu \nu \varrho \sigma }\,\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\varrho }\gamma ^{\sigma }={\frac {i}{4!}}\varepsilon _{\mu \nu \varrho \sigma }\,\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\varrho }\gamma ^{\sigma }=-{\frac {i}{4!}}\varepsilon ^{\mu \nu \varrho \sigma }\,\gamma _{\mu }\gamma _{\nu }\gamma _{\varrho }\gamma _{\sigma }}$

This matrix is useful in discussions of quantum mechanical chirality. For example, a Dirac field can be projected onto its left-handed and right-handed components by:

${\displaystyle \psi _{\rm {L}}={\frac {1-\gamma ^{5}}{2}}\psi ,\qquad \psi _{\rm {R}}={\frac {1+\gamma ^{5}}{2}}\psi }$.

Some properties are:

• It is hermitian:

  ${\displaystyle \left(\gamma ^{5}\right)^{\dagger }=\gamma ^{5}.}$

• Its eigenvalues are ±1, because:

  ${\displaystyle \left(\gamma ^{5}\right)^{2}=I_{4}.}$

• It anticommutes with the four gamma matrices:

  ${\displaystyle \left\{\gamma ^{5},\gamma ^{\mu }\right\}=\gamma ^{5}\gamma ^{\mu }+\gamma ^{\mu }\gamma ^{5}=0.}$

In fact, ${\displaystyle \psi _{\rm {L}}}$ and ${\displaystyle \psi _{\rm {R}}}$ are eigenvectors of ${\displaystyle \gamma ^{5}}$ since

${\displaystyle \gamma ^{5}\psi _{\rm {L}}={\frac {\gamma ^{5}-\left(\gamma ^{5}\right)^{2}}{2}}\psi =-\psi _{\rm {L}}}$, and ${\displaystyle \gamma ^{5}\psi _{\rm {R}}={\frac {\gamma ^{5}+\left(\gamma ^{5}\right)^{2}}{2}}\psi =\psi _{\rm {R}}.}$

Five dimensions[]

The Clifford algebra in odd dimensions behaves like two copies of the Clifford algebra of one less dimension, a left copy and a right copy.^[1] Thus, one can employ a bit of a trick to repurpose iγ⁵ as one of the generators of the Clifford algebra in five dimensions. In this case, the set {γ⁰, γ¹, γ², γ³, iγ⁵} therefore, by the last two properties (keeping in mind that i² = −1) and those of the old gammas, forms the basis of the Clifford algebra in 5 spacetime dimensions for the metric signature (1,4).^[2] In metric signature (4,1), the set {γ⁰, γ¹, γ², γ³, γ⁵} is used, where the γ^μ are the appropriate ones for the (3,1) signature.^[3] This pattern is repeated for spacetime dimension 2n even and the next odd dimension 2n + 1 for all n ≥ 1.^[4] For more detail, see Higher-dimensional gamma matrices.

Identities[]

The following identities follow from the fundamental anticommutation relation, so they hold in any basis (although the last one depends on the sign choice for ${\displaystyle \gamma ^{5}}$).

Miscellaneous identities[]

Trace identities[]

The gamma matrices obey the following trace identities:

Proving the above involves the use of three main properties of the trace operator:

• tr(A + B) = tr(A) + tr(B)
• tr(rA) = r tr(A)
• tr(ABC) = tr(CAB) = tr(BCA)

Proof of 0:

From the definition of the gamma matrices,

${\displaystyle \gamma ^{\mu }\gamma ^{\nu }+\gamma ^{\nu }\gamma ^{\mu }=2\eta ^{\mu \nu }I}$

We get

${\displaystyle \gamma ^{\mu }\gamma ^{\mu }=\eta ^{\mu \mu }I}$

or equivalently,

${\displaystyle {\frac {\gamma ^{\mu }\gamma ^{\mu }}{\eta ^{\mu \mu }}}=I}$

where ${\displaystyle \eta ^{\mu \mu }}$ is a number, and ${\displaystyle \gamma ^{\mu }\gamma ^{\mu }}$ is a matrix.

${\displaystyle \operatorname {tr} (\gamma ^{\nu })={\frac {1}{\eta ^{\mu \mu }}}\operatorname {tr} (\gamma ^{\nu }\gamma ^{\mu }\gamma ^{\mu })}$ (inserting the identity and using tr(rA) = r tr(A))

${\displaystyle =-{\frac {1}{\eta ^{\mu \mu }}}\operatorname {tr} (\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\mu })}$ (from anti-commutation relation, and given that we are free to select ${\displaystyle \mu \neq \nu }$)

${\displaystyle =-{\frac {1}{\eta ^{\mu \mu }}}\operatorname {tr} (\gamma ^{\nu }\gamma ^{\mu }\gamma ^{\mu })}$ (using tr(ABC) = tr(BCA))

${\displaystyle =-\operatorname {tr} (\gamma ^{\nu })}$ (removing the identity)

This implies ${\displaystyle \operatorname {tr} (\gamma ^{\nu })=0}$

Proof of 1:

To show

${\displaystyle \operatorname {tr} ({\text{odd num of }}\gamma )=0}$

First note that

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\right)=0.}$

We'll also use two facts about the fifth gamma matrix ${\displaystyle \gamma ^{5}}$ that says:

${\displaystyle \left(\gamma ^{5}\right)^{2}=I_{4},\quad \mathrm {and} \quad \gamma ^{\mu }\gamma ^{5}=-\gamma ^{5}\gamma ^{\mu }}$

So lets use these two facts to prove this identity for the first non-trivial case: the trace of three gamma matrices. Step one is to put in one pair of ${\displaystyle \gamma ^{5}}$'s in front of the three original ${\displaystyle \gamma }$'s, and step two is to swap the ${\displaystyle \gamma ^{5}}$ matrix back to the original position, after making use of the cyclicity of the trace.

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)}$	${\displaystyle =\operatorname {tr} \left(\gamma ^{5}\gamma ^{5}\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)}$
	${\displaystyle =-\operatorname {tr} \left(\gamma ^{5}\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\gamma ^{5}\right)}$
	${\displaystyle =-\operatorname {tr} \left(\gamma ^{5}\gamma ^{5}\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)}$ (using tr(ABC) = tr(BCA))
	${\displaystyle =-\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)}$

This can only be fulfilled if

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)=0}$

The extension to 2n + 1 (n integer) gamma matrices, is found by placing two gamma-5s after (say) the 2n-th gamma-matrix in the trace, commuting one out to the right (giving a minus sign) and commuting the other gamma-5 2n steps out to the left [with sign change (-1)^2n = 1]. Then we use cyclic identity to get the two gamma-5s together, and hence they square to identity, leaving us with the trace equalling minus itself, i.e. 0.

Proof of 2:

If an odd number of gamma matrices appear in a trace followed by ${\displaystyle \gamma ^{5}}$, our goal is to move ${\displaystyle \gamma ^{5}}$ from the right side to the left. This will leave the trace invariant by the cyclic property. In order to do this move, we must anticommute it with all of the other gamma matrices. This means that we anticommute it an odd number of times and pick up a minus sign. A trace equal to the negative of itself must be zero.

Proof of 3:

To show

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\right)=4\eta ^{\mu \nu }}$

Begin with,

${\displaystyle \operatorname {tr} (\gamma ^{\mu }\gamma ^{\nu })}$	${\displaystyle ={\frac {1}{2}}\left(\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\right)+\operatorname {tr} \left(\gamma ^{\nu }\gamma ^{\mu }\right)\right)}$
	${\displaystyle ={\frac {1}{2}}\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }+\gamma ^{\nu }\gamma ^{\mu }\right)={\frac {1}{2}}\operatorname {tr} \left(\left\{\gamma ^{\mu },\gamma ^{\nu }\right\}\right)}$
	${\displaystyle ={\frac {1}{2}}2\eta ^{\mu \nu }\operatorname {tr} (I_{4})=4\eta ^{\mu \nu }}$

Proof of 4:

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\gamma ^{\sigma }\right)}$	${\displaystyle =\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\left(2\eta ^{\rho \sigma }-\gamma ^{\sigma }\gamma ^{\rho }\right)\right)}$
	${\displaystyle =2\eta ^{\rho \sigma }\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\right)-\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\sigma }\gamma ^{\rho }\right)\quad \quad (1)}$

For the term on the right, we'll continue the pattern of swapping ${\displaystyle \gamma ^{\sigma }}$ with its neighbor to the left,

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\sigma }\gamma ^{\rho }\right)}$	${\displaystyle =\operatorname {tr} \left(\gamma ^{\mu }\left(2\eta ^{\nu \sigma }-\gamma ^{\sigma }\gamma ^{\nu }\right)\gamma ^{\rho }\right)}$
	${\displaystyle =2\eta ^{\nu \sigma }\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\rho }\right)-\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\sigma }\gamma ^{\nu }\gamma ^{\rho }\right)\quad \quad (2)}$

Again, for the term on the right swap ${\displaystyle \gamma ^{\sigma }}$ with its neighbor to the left,

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\sigma }\gamma ^{\nu }\gamma ^{\rho }\right)}$	${\displaystyle =\operatorname {tr} \left(\left(2\eta ^{\mu \sigma }-\gamma ^{\sigma }\gamma ^{\mu }\right)\gamma ^{\nu }\gamma ^{\rho }\right)}$
	${\displaystyle =2\eta ^{\mu \sigma }\operatorname {tr} \left(\gamma ^{\nu }\gamma ^{\rho }\right)-\operatorname {tr} \left(\gamma ^{\sigma }\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)\quad \quad (3)}$

Eq (3) is the term on the right of eq (2), and eq (2) is the term on the right of eq (1). We'll also use identity number 3 to simplify terms like so:

${\displaystyle 2\eta ^{\rho \sigma }\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\right)=2\eta ^{\rho \sigma }\left(4\eta ^{\mu \nu }\right)=8\eta ^{\rho \sigma }\eta ^{\mu \nu }.}$

So finally Eq (1), when you plug all this information in gives

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\gamma ^{\sigma }\right)=8\eta ^{\rho \sigma }\eta ^{\mu \nu }-8\eta ^{\nu \sigma }\eta ^{\mu \rho }+8\eta ^{\mu \sigma }\eta ^{\nu \rho }}$

${\displaystyle -\ \operatorname {tr} \left(\gamma ^{\sigma }\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)\quad \quad \quad \quad \quad \quad (4)}$

The terms inside the trace can be cycled, so

${\displaystyle \operatorname {tr} \left(\gamma ^{\sigma }\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\right)=\operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\gamma ^{\sigma }\right).}$

So really (4) is

${\displaystyle 2\ \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\gamma ^{\sigma }\right)=8\eta ^{\rho \sigma }\eta ^{\mu \nu }-8\eta ^{\nu \sigma }\eta ^{\mu \rho }+8\eta ^{\mu \sigma }\eta ^{\nu \rho }}$

or

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\gamma ^{\sigma }\right)=4\left(\eta ^{\rho \sigma }\eta ^{\mu \nu }-\eta ^{\nu \sigma }\eta ^{\mu \rho }+\eta ^{\mu \sigma }\eta ^{\nu \rho }\right)}$

Proof of 5:

To show

${\displaystyle \operatorname {tr} \left(\gamma ^{5}\right)=0}$,

begin with

${\displaystyle \operatorname {tr} \left(\gamma ^{5}\right)}$	${\displaystyle =\operatorname {tr} \left(\gamma ^{0}\gamma ^{0}\gamma ^{5}\right)}$	(because ${\displaystyle \gamma ^{0}\gamma ^{0}=I_{4}}$)
	${\displaystyle =-\operatorname {tr} \left(\gamma ^{0}\gamma ^{5}\gamma ^{0}\right)}$	(anti-commute the ${\displaystyle \gamma ^{5}}$ with ${\displaystyle \gamma ^{0}}$)
	${\displaystyle =-\operatorname {tr} \left(\gamma ^{0}\gamma ^{0}\gamma ^{5}\right)}$	(rotate terms within trace)
	${\displaystyle =-\operatorname {tr} \left(\gamma ^{5}\right)}$	(remove ${\displaystyle \gamma ^{0}}$'s)

Add ${\displaystyle \operatorname {tr} \left(\gamma ^{5}\right)}$ to both sides of the above to see

${\displaystyle 2\operatorname {tr} \left(\gamma ^{5}\right)=0}$.

Now, this pattern can also be used to show

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{5}\right)=0}$.

Simply add two factors of ${\displaystyle \gamma ^{\alpha }}$, with ${\displaystyle \alpha }$ different from ${\displaystyle \mu }$ and ${\displaystyle \nu }$. Anticommute three times instead of once, picking up three minus signs, and cycle using the cyclic property of the trace.

So,

${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{5}\right)=0}$.

Proof of 6:

For a proof of identity 6, the same trick still works unless ${\displaystyle \left(\mu \nu \rho \sigma \right)}$ is some permutation of (0123), so that all 4 gammas appear. The anticommutation rules imply that interchanging two of the indices changes the sign of the trace, so ${\displaystyle \operatorname {tr} \left(\gamma ^{\mu }\gamma ^{\nu }\gamma ^{\rho }\gamma ^{\sigma }\gamma ^{5}\right)}$ must be proportional to ${\displaystyle \epsilon ^{\mu \nu \rho \sigma }}$ ${\displaystyle \left(\epsilon ^{0123}=\eta ^{0\mu }\eta ^{1\nu }\eta ^{2\rho }\eta ^{3\sigma }\epsilon _{\mu \nu \rho \sigma }=\eta ^{00}\eta ^{11}\eta ^{22}\eta ^{33}\epsilon _{0123}=-1\right)}$. The proportionality constant is ${\displaystyle 4i}$, as can be checked by plugging in ${\displaystyle (\mu \nu \rho \sigma )=(0123)}$, writing out ${\displaystyle \gamma ^{5}}$, and remembering that the trace of the identity is 4.

Proof of 7:

Denote the product of ${\displaystyle n}$ gamma matrices by ${\displaystyle \Gamma =\gamma ^{\mu 1}\gamma ^{\mu 2}\dots \gamma ^{\mu n}.}$ Consider the Hermitian conjugate of ${\displaystyle \Gamma }$:

${\displaystyle \Gamma ^{\dagger }}$	${\displaystyle =\gamma ^{\mu n\dagger }\dots \gamma ^{\mu 2\dagger }\gamma ^{\mu 1\dagger }}$
	${\displaystyle =\gamma ^{0}\gamma ^{\mu n}\gamma ^{0}\dots \gamma ^{0}\gamma ^{\mu 2}\gamma ^{0}\gamma ^{0}\gamma ^{\mu 1}\gamma ^{0}}$	(since conjugating a gamma matrix with ${\displaystyle \gamma ^{0}}$ produces its Hermitian conjugate as described below)
	${\displaystyle =\gamma ^{0}\gamma ^{\mu n}\dots \gamma ^{\mu 2}\gamma ^{\mu 1}\gamma ^{0}}$	(all ${\displaystyle \gamma ^{0}}$s except the first and the last drop out)

Conjugating with ${\displaystyle \gamma ^{0}}$ one more time to get rid of the two ${\displaystyle \gamma ^{0}}$s that are there, we see that ${\displaystyle \gamma ^{0}\Gamma ^{\dagger }\gamma ^{0}}$ is the reverse of ${\displaystyle \Gamma }$. Now,

${\displaystyle \operatorname {tr} \left(\gamma ^{0}\Gamma ^{\dagger }\gamma ^{0}\right)}$	${\displaystyle =\operatorname {tr} \left(\Gamma ^{\dagger }\right)}$	(since trace is invariant under similarity transformations)
	${\displaystyle =\operatorname {tr} \left(\Gamma ^{*}\right)}$	(since trace is invariant under transposition)
	${\displaystyle =\operatorname {tr} \left(\Gamma \right)}$	(since the trace of a product of gamma matrices is real)

Normalization[]

The gamma matrices can be chosen with extra hermiticity conditions which are restricted by the above anticommutation relations however. We can impose

${\displaystyle \left(\gamma ^{0}\right)^{\dagger }=\gamma ^{0}}$, compatible with ${\displaystyle \left(\gamma ^{0}\right)^{2}=I_{4}}$

and for the other gamma matrices (for k = 1, 2, 3)

${\displaystyle \left(\gamma ^{k}\right)^{\dagger }=-\gamma ^{k}}$, compatible with ${\displaystyle \left(\gamma ^{k}\right)^{2}=-I_{4}.}$

One checks immediately that these hermiticity relations hold for the Dirac representation.

The above conditions can be combined in the relation

${\displaystyle \left(\gamma ^{\mu }\right)^{\dagger }=\gamma ^{0}\gamma ^{\mu }\gamma ^{0}.}$

The hermiticity conditions are not invariant under the action ${\displaystyle \gamma ^{\mu }\to S(\Lambda )\gamma ^{\mu }{S(\Lambda )}^{-1}}$ of a Lorentz transformation ${\displaystyle \Lambda }$ because ${\displaystyle S(\Lambda )}$ is not necessarily a unitary transformation due to the non-compactness of the Lorentz group.

Charge conjugation[]

The charge conjugation operator, in any basis, may be defined as

${\displaystyle C\gamma _{\mu }C^{-1}=-(\gamma _{\mu })^{\textsf {T}}}$

where ${\displaystyle (\cdot )^{\textsf {T}}}$ denotes the matrix transpose. The explicit form that ${\displaystyle C}$ takes is dependent on the specific representation chosen for the gamma matrices (its form expressed as product of the gamma matrices is representation independent, but the gamma matrices themselves have different forms in different representation). This is because although charge conjugation is an automorphism of the gamma group, it is not an inner automorphism (of the group). Conjugating matrices can be found, but they are representation-dependent.

Representation-independent identities include:

${\displaystyle {\begin{aligned}C\gamma _{5}C^{-1}&=+(\gamma _{5})^{\textsf {T}}\\C\sigma _{\mu \nu }C^{-1}&=-(\sigma _{\mu \nu })^{\textsf {T}}\\C\gamma _{5}\gamma _{\mu }C^{-1}&=+(\gamma _{5}\gamma _{\mu })^{\textsf {T}}\\\end{aligned}}}$

In addition, for all four representations given below (Dirac, Majorana and both chiral variants), one has

${\displaystyle C^{-1}=C^{\dagger }=C^{\textsf {T}}=-C.}$

Feynman slash notation used in quantum field theory[]

The Feynman slash notation is defined by

${\displaystyle {a\!\!\!/}:=\gamma ^{\mu }a_{\mu }}$

for any 4-vector a.

Here are some similar identities to the ones above, but involving slash notation:

• ${\displaystyle {a\!\!\!/}{b\!\!\!/}=a\cdot b-ia_{\mu }\sigma ^{\mu \nu }b_{\nu }}$
• ${\displaystyle {a\!\!\!/}{a\!\!\!/}=a^{\mu }a^{\nu }\gamma _{\mu }\gamma _{\nu }={\frac {1}{2}}a^{\mu }a^{\nu }\left(\gamma _{\mu }\gamma _{\nu }+\gamma _{\nu }\gamma _{\mu }\right)=\eta _{\mu \nu }a^{\mu }a^{\nu }=a^{2}}$
• ${\displaystyle \operatorname {tr} \left({a\!\!\!/}{b\!\!\!/}\right)=4(a\cdot b)}$
• ${\displaystyle \operatorname {tr} \left({a\!\!\!/}{b\!\!\!/}{c\!\!\!/}{d\!\!\!/}\right)=4\left[(a\cdot b)(c\cdot d)-(a\cdot c)(b\cdot d)+(a\cdot d)(b\cdot c)\right]}$
• ${\displaystyle \operatorname {tr} \left(\gamma _{5}{a\!\!\!/}{b\!\!\!/}\right)=0}$
• ${\displaystyle \operatorname {tr} \left(\gamma _{5}{a\!\!\!/}{b\!\!\!/}{c\!\!\!/}{d\!\!\!/}\right)=-4i\epsilon _{\mu \nu \rho \sigma }a^{\mu }b^{\nu }c^{\rho }d^{\sigma }}$
• ${\displaystyle \gamma _{\mu }{a\!\!\!/}\gamma ^{\mu }=-2{a\!\!\!/}}$
• ${\displaystyle \gamma _{\mu }{a\!\!\!/}{b\!\!\!/}\gamma ^{\mu }=4(a\cdot b)}$
• ${\displaystyle \gamma _{\mu }{a\!\!\!/}{b\!\!\!/}{c\!\!\!/}\gamma ^{\mu }=-2{c\!\!\!/}{b\!\!\!/}{a\!\!\!/}}$

  where ${\displaystyle \epsilon _{\mu \nu \rho \sigma }}$ is the Levi-Civita symbol and ${\displaystyle \sigma ^{\mu \nu }={\frac {i}{2}}\left[\gamma ^{\mu },\gamma ^{\nu }\right].}$ Actually traces of products of odd number of ${\displaystyle \gamma }$ is zero and thus

• ${\displaystyle \operatorname {tr} \left({a\!\!\!/}\right)=\operatorname {tr} \left({a\!\!\!/}{b\!\!\!/}{c\!\!\!/}\right)=\operatorname {tr} \left({a\!\!\!/}{b\!\!\!/}{c\!\!\!/}{d\!\!\!/}{e\!\!\!/}\right)=0}$^[5]

Other representations[]

The matrices are also sometimes written using the 2×2 identity matrix, ${\displaystyle I_{2}}$, and

${\displaystyle \gamma ^{k}={\begin{pmatrix}0&\sigma ^{k}\\-\sigma ^{k}&0\end{pmatrix}}}$

where k runs from 1 to 3 and the σ^k are Pauli matrices.

Dirac basis[]

The gamma matrices we have written so far are appropriate for acting on Dirac spinors written in the Dirac basis; in fact, the Dirac basis is defined by these matrices. To summarize, in the Dirac basis:

${\displaystyle \gamma ^{0}={\begin{pmatrix}I_{2}&0\\0&-I_{2}\end{pmatrix}},\quad \gamma ^{k}={\begin{pmatrix}0&\sigma ^{k}\\-\sigma ^{k}&0\end{pmatrix}},\quad \gamma ^{5}={\begin{pmatrix}0&I_{2}\\I_{2}&0\end{pmatrix}}.}$

In the Dirac basis, the charge conjugation operator is^[6]

${\displaystyle C=i\gamma ^{2}\gamma ^{0}={\begin{pmatrix}0&-i\sigma ^{2}\\-i\sigma ^{2}&0\end{pmatrix}}.}$

Weyl (chiral) basis[]

Another common choice is the Weyl or chiral basis, in which ${\displaystyle \gamma ^{k}}$ remains the same but ${\displaystyle \gamma ^{0}}$ is different, and so ${\displaystyle \gamma ^{5}}$ is also different, and diagonal,

${\displaystyle \gamma ^{0}={\begin{pmatrix}0&I_{2}\\I_{2}&0\end{pmatrix}},\quad \gamma ^{k}={\begin{pmatrix}0&\sigma ^{k}\\-\sigma ^{k}&0\end{pmatrix}},\quad \gamma ^{5}={\begin{pmatrix}-I_{2}&0\\0&I_{2}\end{pmatrix}},}$

or in more compact notation:

${\displaystyle \gamma ^{\mu }={\begin{pmatrix}0&\sigma ^{\mu }\\{\overline {\sigma }}^{\mu }&0\end{pmatrix}},\quad \sigma ^{\mu }\equiv (1,\sigma ^{i}),\quad {\overline {\sigma }}^{\mu }\equiv \left(1,-\sigma ^{i}\right).}$

The Weyl basis has the advantage that its chiral projections take a simple form,

${\displaystyle \psi _{\rm {L}}={\frac {1}{2}}\left(1-\gamma ^{5}\right)\psi ={\begin{pmatrix}I_{2}&0\\0&0\end{pmatrix}}\psi ,\quad \psi _{\rm {R}}={\frac {1}{2}}\left(1+\gamma ^{5}\right)\psi ={\begin{pmatrix}0&0\\0&I_{2}\end{pmatrix}}\psi .}$

The idempotence of the chiral projections is manifest.

By slightly abusing the notation and reusing the symbols ${\displaystyle \psi _{\rm {L/R}}}$ we can then identify

${\displaystyle \psi ={\begin{pmatrix}\psi _{\rm {L}}\\\psi _{\rm {R}}\end{pmatrix}},}$

where now ${\displaystyle \psi _{\rm {L}}}$ and ${\displaystyle \psi _{\rm {R}}}$ are left-handed and right-handed two-component Weyl spinors.

The charge conjugation operator in this basis is

${\displaystyle C={\begin{pmatrix}i\sigma ^{2}&0\\0&-i\sigma ^{2}\end{pmatrix}}}$

The Dirac basis can be obtained from the Weyl basis as

${\displaystyle \gamma _{\rm {W}}^{\mu }=U\gamma _{\rm {D}}^{\mu }U^{\dagger },\quad \psi _{\rm {W}}=U\psi _{\rm {D}}}$

via the unitary transform

${\displaystyle U={\frac {1}{\sqrt {2}}}\left(1+\gamma ^{5}\gamma ^{0}\right)={\frac {1}{\sqrt {2\,}}}{\begin{pmatrix}I_{2}&-I_{2}\\I_{2}&I_{2}\end{pmatrix}}.}$

Weyl (chiral) basis (alternate form)[]

Another possible choice^[6][7] of the Weyl basis has

${\displaystyle \gamma ^{0}={\begin{pmatrix}0&-I_{2}\\-I_{2}&0\end{pmatrix}},\quad \gamma ^{k}={\begin{pmatrix}0&\sigma ^{k}\\-\sigma ^{k}&0\end{pmatrix}},\quad \gamma ^{5}={\begin{pmatrix}I_{2}&0\\0&-I_{2}\end{pmatrix}}.}$

The chiral projections take a slightly different form from the other Weyl choice,

${\displaystyle \psi _{\rm {R}}={\begin{pmatrix}I_{2}&0\\0&0\end{pmatrix}}\psi ,\quad \psi _{\rm {L}}={\begin{pmatrix}0&0\\0&I_{2}\end{pmatrix}}\psi .}$

In other words,

${\displaystyle \psi ={\begin{pmatrix}\psi _{\rm {R}}\\\psi _{\rm {L}}\end{pmatrix}},}$

where ${\displaystyle \psi _{\rm {L}}}$ and ${\displaystyle \psi _{\rm {R}}}$ are the left-handed and right-handed two-component Weyl spinors, as before.

The charge conjugation operator in this basis is

${\displaystyle C=-i\sigma ^{3}\otimes \sigma ^{2}={\begin{pmatrix}-i\sigma ^{2}&0\\0&i\sigma ^{2}\end{pmatrix}}}$

This basis can be obtained from the Dirac basis above as ${\displaystyle \gamma _{\rm {W}}^{\mu }=U\gamma _{\rm {D}}^{\mu }U^{\dagger },~~\psi _{\rm {W}}=U\psi _{\rm {D}}}$ via the unitary transform

${\displaystyle U={\frac {1}{\sqrt {2}}}\left(1-\gamma ^{5}\gamma ^{0}\right)={\frac {1}{\sqrt {2\,}}}{\begin{pmatrix}I_{2}&I_{2}\\-I_{2}&I_{2}\end{pmatrix}}.}$

Majorana basis[]

There is also the Majorana basis, in which all of the Dirac matrices are imaginary, and the spinors and Dirac equation are real. Regarding the Pauli matrices, the basis can be written as^[6]

${\displaystyle {\begin{aligned}\gamma ^{0}&={\begin{pmatrix}0&\sigma ^{2}\\\sigma ^{2}&0\end{pmatrix}},&\gamma ^{1}&={\begin{pmatrix}i\sigma ^{3}&0\\0&i\sigma ^{3}\end{pmatrix}},&\gamma ^{2}&={\begin{pmatrix}0&-\sigma ^{2}\\\sigma ^{2}&0\end{pmatrix}},\\\gamma ^{3}&={\begin{pmatrix}-i\sigma ^{1}&0\\0&-i\sigma ^{1}\end{pmatrix}},&\gamma ^{5}&={\begin{pmatrix}\sigma ^{2}&0\\0&-\sigma ^{2}\end{pmatrix}},&C&={\begin{pmatrix}0&-i\sigma ^{2}\\-i\sigma ^{2}&0\end{pmatrix}},\end{aligned}}}$

where ${\displaystyle C}$ is the charge conjugation matrix, as defined above.

(The reason for making all gamma matrices imaginary is solely to obtain the particle physics metric (+, −, −, −), in which squared masses are positive. The Majorana representation, however, is real. One can factor out the i to obtain a different representation with four component real spinors and real gamma matrices. The consequence of removing the ${\displaystyle i}$ is that the only possible metric with real gamma matrices is (−, +, +, +).)

The Majorana basis can be obtained from the Dirac basis above as ${\displaystyle \gamma _{\rm {M}}^{\mu }=U\gamma _{\rm {D}}^{\mu }U^{\dagger },~~\psi _{\rm {M}}=U\psi _{\rm {D}}}$ via the unitary transform

${\displaystyle U=U^{\dagger }={\frac {1}{\sqrt {2\,}}}{\begin{pmatrix}I_{2}&\sigma ^{2}\\\sigma ^{2}&-I_{2}\end{pmatrix}}.}$

Cl_1,3(C) and Cl_1,3(R)[]

The Dirac algebra can be regarded as a complexification of the real algebra Cl_1,3(R), called the space time algebra:

${\displaystyle \mathrm {Cl} _{1,3}(\mathbb {C} )=\mathrm {Cl} _{1,3}(\mathbb {R} )\otimes \mathbb {C} }$

Cl_1,3(R) differs from Cl_1,3(C): in Cl_1,3(R) only real linear combinations of the gamma matrices and their products are allowed.

Two things deserve to be pointed out. As Clifford algebras, Cl_1,3(C) and Cl₄(C) are isomorphic, see classification of Clifford algebras. The reason is that the underlying signature of the spacetime metric loses its signature (1,3) upon passing to the complexification. However, the transformation required to bring the bilinear form to the complex canonical form is not a Lorentz transformation and hence not "permissible" (at the very least impractical) since all physics is tightly knit to the Lorentz symmetry and it is preferable to keep it manifest.

Proponents of geometric algebra strive to work with real algebras wherever that is possible. They argue that it is generally possible (and usually enlightening) to identify the presence of an imaginary unit in a physical equation. Such units arise from one of the many quantities in a real Clifford algebra that square to −1, and these have geometric significance because of the properties of the algebra and the interaction of its various subspaces. Some of these proponents also question whether it is necessary or even useful to introduce an additional imaginary unit in the context of the Dirac equation.^[8]

In the mathematics of Riemannian geometry, it is conventional to define the Clifford algebra Cl_p,q(ℝ) for arbitrary dimensions p,q; the anti-commutation of the Weyl spinors emerges naturally from the Clifford algebra.^[9] The Weyl spinors transform under the action of the spin group ${\displaystyle \mathrm {Spin} (n)}$. The complexification of the spin group, called the spinc group ${\displaystyle \mathrm {Spin} ^{\mathbb {C} }(n)}$, is a product ${\displaystyle \mathrm {Spin} (n)\times _{\mathbb {Z} _{2}}S^{1}}$ of the spin group with the circle ${\displaystyle S^{1}\cong U(1).}$ The product ${\displaystyle \times _{\mathbb {Z} _{2}}}$ just a notational device to identify ${\displaystyle (a,u)\in \mathrm {Spin} (n)\times S^{1}}$ with ${\displaystyle (-a,-u).}$ The geometric point of this is that it disentangles the real spinor, which is covariant under Lorentz transformations, from the ${\displaystyle U(1)}$ component, which can be identified with the ${\displaystyle \mathrm {U} (1)}$ fiber of the electromagnetic interaction. The ${\displaystyle \times _{\mathbb {Z} _{2}}}$ is entangling parity and charge conjugation in a manner suitable for relating the Dirac particle/anti-particle states (equivalently, the chiral states in the Weyl basis). The bispinor, insofar as it has linearly independent left and right components, can interact with the electromagnetic field. This is in contrast to the Majorana spinor and the ELKO spinor, which cannot (i.e. they are electrically neutral), as they explicitly constrain the spinor so as to not interact with the ${\displaystyle S^{1}}$ part coming from the complexification.

Insofar as the presentation of charge and parity can be a confusing topic in conventional quantum field theory textbooks, the more careful dissection of these topics in a general geometric setting can be elucidating. Standard expositions of the Clifford algebra construct the Weyl spinors from first principles; that they "automatically" anti-commute is an elegant geometric by-product of the construction, completely by-passing any arguments that appeal to the Pauli exclusion principle (or the sometimes common sensation that Grassmann variables have been introduced via ad hoc argumentation.)

However, in contemporary practice in physics, the Dirac algebra rather than the space-time algebra continues to be the standard environment the spinors of the Dirac equation "live" in.

Euclidean Dirac matrices[]

In quantum field theory one can Wick rotate the time axis to transit from Minkowski space to Euclidean space. This is particularly useful in some renormalization procedures as well as lattice gauge theory. In Euclidean space, there are two commonly used representations of Dirac matrices:

Chiral representation[]

${\displaystyle \gamma ^{1,2,3}={\begin{pmatrix}0&i\sigma ^{1,2,3}\\-i\sigma ^{1,2,3}&0\end{pmatrix}},\quad \gamma ^{4}={\begin{pmatrix}0&I_{2}\\I_{2}&0\end{pmatrix}}}$

Notice that the factors of ${\displaystyle i}$ have been inserted in the spatial gamma matrices so that the Euclidean Clifford algebra

${\displaystyle \left\{\gamma ^{\mu },\gamma ^{\nu }\right\}=2\delta ^{\mu \nu }I_{4}}$

will emerge. It is also worth noting that there are variants of this which insert instead ${\displaystyle -i}$ on one of the matrices, such as in lattice QCD codes which use the chiral basis.

In Euclidean space,

${\displaystyle \gamma _{\rm {M}}^{5}=i\left(\gamma ^{0}\gamma ^{1}\gamma ^{2}\gamma ^{3}\right)_{\rm {M}}={\frac {1}{i^{2}}}\left(\gamma ^{4}\gamma ^{1}\gamma ^{2}\gamma ^{3}\right)_{\rm {E}}=\left(\gamma ^{1}\gamma ^{2}\gamma ^{3}\gamma ^{4}\right)_{\rm {E}}=\gamma _{\rm {E}}^{5}.}$

Using the anti-commutator and noting that in Euclidean space ${\displaystyle \left(\gamma ^{\mu }\right)^{\dagger }=\gamma ^{\mu }}$, one shows that

${\displaystyle \left(\gamma ^{5}\right)^{\dagger }=\gamma ^{5}}$

In chiral basis in Euclidean space,

${\displaystyle \gamma ^{5}={\begin{pmatrix}-I_{2}&0\\0&I_{2}\end{pmatrix}}}$

which is unchanged from its Minkowski version.

Non-relativistic representation[]

${\displaystyle \gamma ^{1,2,3}={\begin{pmatrix}0&-i\sigma ^{1,2,3}\\i\sigma ^{1,2,3}&0\end{pmatrix}},\quad \gamma ^{4}={\begin{pmatrix}I_{2}&0\\0&-I_{2}\end{pmatrix}},\quad \gamma ^{5}={\begin{pmatrix}0&-I_{2}\\-I_{2}&0\end{pmatrix}}}$

See also[]

• Pauli matrices
• Gell-Mann matrices
• Higher-dimensional gamma matrices
• Fierz identity

References[]

• Halzen, Francis; Martin, Alan (1984). Quarks & Leptons: An Introductory Course in Modern Particle Physics. John Wiley & Sons. ISBN 0-471-88741-2.
• A. Zee, Quantum Field Theory in a Nutshell (2003), Princeton University Press: Princeton, New Jersey. ISBN 0-691-01019-6. See chapter II.1.
• M. Peskin, D. Schroeder, An Introduction to Quantum Field Theory (Westview Press, 1995) ISBN 0-201-50397-2 See chapter 3.2.
• W. Pauli (1936). "Contributions mathématiques à la théorie des matrices de Dirac". Annales de l'Institut Henri Poincaré. 6: 109.
• Weinberg, S. (2002), The Quantum Theory of Fields, 1, Cambridge University Press, ISBN 0-521-55001-7
• Tong, David (2007). "Quantum Field Theory". David Tong at University of Cambridge. p. 93. Retrieved 2015-03-07.
• de Wit, B.; Smith, J. (1986). Field Theory in Particle Physics. North-Holland Personal Library. 1. North-Holland. ISBN 978-0444869999.Appendix E
• David Hestenes, Real Dirac Theory, in J. Keller and Z. Oziewicz (Eds.), The Theory of the Electron, UNAM, Facultad de Estudios Superiores, Cuautitlan, Mexico (1996), pp. 1–50.

External links[]

• Dirac matrices on mathworld including their group properties
• Dirac matrices as an abstract group on GroupNames
• "Dirac matrices", Encyclopedia of Mathematics, EMS Press, 2001 [1994]