For rotations and boosts,γ 5 commutes withSsince it commutes with the pair of gamma matrices.
For a parity inversion, it anticommutes withSP =γ 4. Therefore its easy to show thatψγ ̄ 5 ψ
transforms like apseudoscalarandψiγ ̄ 5 γμψtransforms like anaxial vector. This now brings
our total to 16 components of bilinear (in the spinor) covariants. Note that things likeγ 5 σ 12 =
iγ 1 γ 2 γ 3 γ 4 γ 1 γ 2 =−iγ 3 γ 4 is just a constant times another antisymmetric tensor element, soits nothing
new.
Classification Covariant Form no. of ComponentsScalar ψψ ̄ 1
Pseudoscalar ψγ ̄ 5 ψ 1
Vector ψγ ̄μψ 4
Axial Vector ψγ ̄ 5 γμψ 4
Rank 2 antisymmetric tensor ψσ ̄μνψ 6
Total 16Theγmatrices can be used along with Dirac spinors to make a Lorentz scalar, pseudoscalar, vector,
axial vector and rank 2 tensor. This is thecomplete set of covariants, which of course could be
used together to make up Lagrangians for physical quantities. Allsixteen quantities defined satisfy
Γ^2 = 1.
36.12Constants of the Motion for a Free Particle
We know that operators representingconstants of the motion commute with the Hamilto-
nian. The form of the Dirac equation we have been using does not have a clear Hamiltonian. This
is true essentially because of the covariant form we have been using. For a Hamiltonian formulation,
we need to separate the space and time derivatives. Lets find theHamiltonian in the Dirac
equation.
(
γμ
∂
∂xμ+
mc
̄h)
ψ= 0
(
γj∂
∂xj+γ 4∂
∂ict+
mc
̄h)
ψ= 0
(
γjpj−γ 4̄h
c∂
∂t−imc)
ψ= 0(γjpj−imc)ψ=γ 4̄h
c∂ψ
∂t
(γ 4 γjpj−imcγ 4 )ψ=
̄h
c∂ψ
( ∂t
icγ 4 γjpj+mc^2 γ 4)
ψ=EψH=icγ 4 γjpj+mc^2 γ 4Its easy to see thepkcommutes with the Hamiltonian for a free particle so thatmomentum will
be conserved.