In theoretical physics, a supermultiplet is a representation of a supersymmetry algebra, possibly with extended supersymmetry.
Then a superfield is a field on superspace which is valued in such a representation. Naïvely, or when considering flat superspace, a superfield can simply be viewed as a function on superspace. Formally, it is a section of an associated supermultiplet bundle.
Phenomenologically, superfields are used to describe particles. It is a feature of supersymmetric field theories that particles form pairs, called superpartners where bosons are paired with fermions.
These supersymmetric fields are used to build supersymmetric quantum field theories, where the fields are promoted to operators.
Superfields were introduced by Abdus Salam and J. A. Strathdee in a 1974 article.[1] Operations on superfields and a partial classification were presented a few months later by Sergio Ferrara, Julius Wess and Bruno Zumino.[2]
The most commonly used supermultiplets are vector multiplets, chiral multiplets (in
d=4,l{N}=1
d=4,l{N}=2
The use of these names for the different multiplets can vary in literature. A chiral multiplet (whose highest component is a spinor) may sometimes be referred to as a scalar multiplet, and in
d=4,l{N}=2
Conventions in this section follow the notes by .
A general complex superfield
\Phi(x,\theta,\bar\theta)
d=4,l{N}=1
\Phi(x,\theta,\bar\theta)=\phi(x)+\theta\chi(x)+\bar\theta\bar\chi'(x)+\bar\theta\sigma\mu\thetaV\mu(x)+\theta2F(x)+\bar\theta2\barF'(x)+\bar\theta2\theta\xi(x)+\theta2\bar\theta\bar\xi'(x)+\theta2\bar\theta2D(x)
where
\phi,\chi,\bar\chi',V\mu,F,\barF',\xi,\bar\xi',D
A (anti-)chiral superfield is a supermultiplet of
d=4,l{N}=1
In four dimensions, the minimal
l{N}=1
x\mu
\mu=0,\ldots,3
| |||
| \theta | |||
| \alpha,\bar\theta |
\alpha,
| \alpha |
=1,2
In
d=4,l{N}=1
\Phi(x,\theta,\bar\theta)
\overline{D}\Phi=0
\barD
\bar
| D | |||
|
=
| -\bar\partial | |||
|
-i\theta\alpha
| \mu | |||
| \sigma | |||
|
\partial\mu.
A chiral superfield
\Phi(x,\theta,\bar\theta)
\Phi(y,\theta)=\phi(y)+\sqrt{2}\theta\psi(y)+\theta2F(y),
y\mu=x\mu+i\theta\sigma\mu\bar{\theta}
\bar\theta
\bar\theta
y\mu
\bar
| D | |||
|
y\mu=0.
The expansion has the interpretation that
\phi
\psi
F
F
The field can then be expressed in terms of the original coordinates
(x,\theta,\bar\theta)
y
\Phi(x,\theta,\bar\theta)=\phi(x)+\sqrt{2}\theta\psi(x)+\theta2F(x)+
| \mu\bar\theta\partial | |
| i\theta\sigma | |
| \mu\phi(x) |
-
| i | |
| \sqrt{2 |
Similarly, there is also antichiral superspace, which is the complex conjugate of chiral superspace, and antichiral superfields.
An antichiral superfield
\Phi\dagger
D\Phi\dagger=0,
D\alpha=\partial\alpha+
| \mu | |||
| i\sigma | |||
|
| |||
| \bar\theta | |||
| \mu. |
An antichiral superfield can be constructed as the complex conjugate of a chiral superfield.
For an action which can be defined from a single chiral superfield, see Wess–Zumino model.
The vector superfield is a supermultiplet of
l{N}=1
A vector superfield (also known as a real superfield) is a function
V(x,\theta,\bar\theta)
V=V\dagger
V=C+i\theta\chi-i\overline{\theta}\overline{\chi}+\tfrac{i}{2}\theta2(M+iN)-\tfrac{i}{2}\overline{\theta2}(M-iN)-\theta\sigma\mu\overline{\theta}A\mu+i\theta2\overline{\theta}\left(\overline{λ}+\tfrac{i}{2}\overline{\sigma}\mu\partial\mu\chi\right)-i\overline{\theta}2\theta\left(λ+\tfrac{i}{2}\sigma\mu\partial\mu\overline{\chi}\right)+\tfrac{1}{2}\theta2\overline{\theta}2\left(D+\tfrac{1}{2}\BoxC\right).
The constituent fields are
C
D
M+iN
\chi\alpha
λ\alpha
A\mu
Their transformation properties and uses are further discussed in supersymmetric gauge theory.
Using gauge transformations, the fields
C,\chi
M+iN
VWZ=\theta\sigma\mu\bar\thetaA\mu+\theta2\bar\theta\barλ+\bar\theta2\thetaλ+
| 1 | |
| 2 |
\theta2\bar\theta2D.
λ
A\mu
D
D
A scalar is never the highest component of a superfield; whether it appears in a superfield at all depends on the dimension of the spacetime. For example, in a 10-dimensional N=1 theory the vector multiplet contains only a vector and a Majorana–Weyl spinor, while its dimensional reduction on a d-dimensional torus is a vector multiplet containing d real scalars. Similarly, in an 11-dimensional theory there is only one supermultiplet with a finite number of fields, the gravity multiplet, and it contains no scalars. However again its dimensional reduction on a d-torus to a maximal gravity multiplet does contain scalars.
A hypermultiplet is a type of representation of an extended supersymmetry algebra, in particular the matter multiplet of
l{N}=2
The name "hypermultiplet" comes from old term "hypersymmetry" for N=2 supersymmetry used by ; this term has been abandoned, but the name "hypermultiplet" for some of its representations is still used.
This section records some commonly used irreducible supermultiplets in extended supersymmetry in the
d=4
QA,A=1, … ,l{N}
2l{N}
l{N}
l{N}=8
l{N}
l{N}=4
The
l{N}=2
\Psi
A\mu
λ,\psi
\phi
l{N}=1
l{N}=1
W=(A\mu,λ)
\Phi=(\phi,\psi)
The
l{N}=2
l{N}=1
The
l{N}=4