In quantum field theory, a fermionic field is a quantum field whose quanta are fermions; that is, they obey Fermi–Dirac statistics. Fermionic fields obey canonical anticommutation relations rather than the canonical commutation relations of bosonic fields.
The most prominent example of a fermionic field is the Dirac field, which describes fermions with spin-1/2: electrons, protons, quarks, etc. The Dirac field can be described as either a 4-component spinor or as a pair of 2-component Weyl spinors. Spin-1/2 Majorana fermions, such as the hypothetical neutralino, can be described as either a dependent 4-component Majorana spinor or a single 2-component Weyl spinor. It is not known whether the neutrino is a Majorana fermion or a Dirac fermion; observing neutrinoless double-beta decay experimentally would settle this question.
Free (non-interacting) fermionic fields obey canonical anticommutation relations; i.e., involve the anticommutators = ab + ba, rather than the commutators [''a'', ''b''] = ab − ba of bosonic or standard quantum mechanics. Those relations also hold for interacting fermionic fields in the interaction picture, where the fields evolve in time as if free and the effects of the interaction are encoded in the evolution of the states.
It is these anticommutation relations that imply Fermi–Dirac statistics for the field quanta. They also result in the Pauli exclusion principle: two fermionic particles cannot occupy the same state at the same time.
The prominent example of a spin-1/2 fermion field is the Dirac field (named after Paul Dirac), and denoted by
\psi(x)
\left(i\gamma\mu\partial\mu-m\right)\psi(x)=0.
where
\gamma\mu
m
\psi(x)
u(p)e-ip ⋅
v(p)eip ⋅
\psi(x)
\psi\alpha(x)=\int
d3p | |
(2\pi)3 |
1 | |
\sqrt{2Ep |
u and v are spinors, labelled by spin, s and spinor indices
\alpha\in\{0,1,2,3\}
\psi(x)
s | |
a | |
p |
s\dagger | |
b | |
p |
\psi(x)
\psi(y)\dagger
\left\{\psi\alpha(x),
\dagger(y)\right\} | |
\psi | |
\beta |
=\delta(3)(x-y)\delta\alpha\beta.
We impose an anticommutator relation (as opposed to a commutation relation as we do for the bosonic field) in order to make the operators compatible with Fermi–Dirac statistics. By putting in the expansions for
\psi(x)
\psi(y)
r | |
\left\{a | |
p, |
s\dagger | |
a | |
q\right\} |
=
r | |
\left\{b | |
p, |
s\dagger | |
b | |
q\right\} |
=(2\pi)3\delta3(p-q)\deltars,
In a manner analogous to non-relativistic annihilation and creation operators and their commutators, these algebras lead to the physical interpretation that
s\dagger | |
a | |
p |
r\dagger | |
b | |
q |
\psi(x)
\overline{\psi} \stackrel{def
With the field modes understood and the conjugate field defined, it is possible to construct Lorentz invariant quantities for fermionic fields. The simplest is the quantity
\overline{\psi}\psi
\overline{\psi}=\psi\dagger\gamma0
\psi
\psi\dagger\psi
\gamma0
\overline{\psi}\gamma\mu\partial\mu\psi
Since linear combinations of these quantities are also Lorentz invariant, this leads naturally to the Lagrangian density for the Dirac field by the requirement that the Euler–Lagrange equation of the system recover the Dirac equation.
l{L}D=\overline{\psi}\left(i\gamma\mu\partial\mu-m\right)\psi
Such an expression has its indices suppressed. When reintroduced the full expression is
l{L}D=
\mu | |
\overline{\psi} | |
ab |
\partial\mu-mIab\right)\psib
The Hamiltonian (energy) density can also be constructed by first defining the momentum canonically conjugate to
\psi(x)
\Pi(x):
\Pi \overset{def
With that definition of
\Pi
l{H}D=\overline{\psi}\left[-i\vec{\gamma} ⋅ \vec{\nabla}+m\right]\psi,
where
\vec{\nabla}
\vec{\gamma}
\gamma
\psi
Given the expression for
\psi(x)
DF(x-y)=\left\langle0\left|T(\psi(x)\overline{\psi}(y))\right|0\right\rangle
we define the time-ordered product for fermions with a minus sign due to their anticommuting nature
T\left[\psi(x)\overline{\psi}(y)\right] \overset{def
Plugging our plane wave expansion for the fermion field into the above equation yields:
DF(x-y)=\int
d4p | |
(2\pi)4 |
i({p/ | |
+ |
m)}{p2-m2+i\epsilon}e-ip
where we have employed the Feynman slash notation. This result makes sense since the factor
i({p/ | |
+ |
m)}{p2-m2}
is just the inverse of the operator acting on
\psi(x)
More complicated field theories involving interactions (such as Yukawa theory, or quantum electrodynamics) can be analyzed too, by various perturbative and non-perturbative methods.
Dirac fields are an important ingredient of the Standard Model.