130_notes.dvi

Removing theψ†from the left andψfrom the right and dotting intoA, we have the interaction
Hamiltonian.
Hint=ieγ 4 γμAμ

Note the difference between this interaction and the one we used in the non-relativistic case. The
relativistic interaction has just one term, is linear inA, and is naturally proportional to the coupling
e. There isno longer anA^2 termwith a different power ofe. This will make our perturbation
series also a series in powers ofα.

We may still assume thatAistransverseand thatA 0 = 0 by choice of gauge.

Hint=ieγ 4 γkAk

36.14Phenomena of Dirac States

36.14.1Velocity Operator and Zitterbewegung

We will work for a while in the Heisenberg representation in which the operators depend on time
and we can see some of the general behavior of electrons. If we work in a state of definite energy,
the time dependence of the operators is very simple, just the usual exponentials.

Theoperator for velocityin the x direction can be computed from the commutator with the
Hamiltonian.

x ̇=

i

̄h

[H,x] =

i

̄h

ic[γ 4 γjpj,x] =icγ 4 γ 1

vj=icγ 4 γj

Thevelocity operatorthen isvj=icγ 4 γj.

Its not hard to compute that thevelocity eigenvalues(any component) are±c.

icγ 4 γ 1 =ic







1 0 0 0

0 1 0 0

0 0 −1 0

0 0 0 − 1













0 0 0 −i

0 0 −i 0

0 i 0 0

i 0 0 0





=c







0 0 0 1

0 0 1 0

0 1 0 0

1 0 0 0







c







0 0 0 1

0 0 1 0

0 1 0 0

1 0 0 0













a

b

c

d





=λc







a

b

c

d







∣

∣

∣∣

∣

∣

∣

−λ 0 0 1

0 −λ 1 0

0 1 −λ 0

1 0 0 −λ

∣

∣

∣∣

∣

∣

∣

= 0

−λ[−λ(λ^2 )−1(−λ)]−1[λ(λ) + 1(1)] = 0

λ^4 − 2 λ^2 + 1 = 0

(λ^2 −1)^2 = 0