't Hooft loop explained
In quantum field theory, the 't Hooft loop is a magnetic analogue of the Wilson loop for which spatial loops give rise to thin loops of magnetic flux associated with magnetic vortices. They play the role of a disorder parameter for the Higgs phase in pure gauge theory. Consistency conditions between electric and magnetic charges limit the possible 't Hooft loops that can be used, similarly to the way that the Dirac quantization condition limits the set of allowed magnetic monopoles. They were first introduced by Gerard 't Hooft in 1978 in the context of possible phases that gauge theories admit.[1]
Definition
There are a number of ways to define 't Hooft lines and loops. For timelike curves
they are equivalent to the gauge configuration arising from the
worldline traced out by a magnetic monopole. These are
singular gauge field configurations on the line such that their spatial slice have a
magnetic field whose form approaches that of a magnetic monopole
Bi\xrightarrow{r → 0}
Q(x),
is the generally
Lie algebra valued object specifying the magnetic charge. 't Hooft lines can also be inserted in the
path integral by requiring that the gauge field measure can only run over configurations whose magnetic field takes the above form.
More generally, the 't Hooft loop can be defined as the operator whose effect is equivalent to performing a modified gauge transformations
that is singular on the loop
in such a way that any other loop
parametrized by
with a
winding number
around
satisfies
[2] \Omega(s=1)=ei2\pi\Omega(s=0).
These modified gauge transformations are not true gauge transformations as they do not leave the action invariant. For temporal loops they create the aforementioned field configurations while for spatial loops they instead create loops of color magnetic flux, referred to as center vortices. By constructing such gauge transformations, an explicit form for the 't Hooft loop can be derived by introducing the Yang–Mills conjugate momentum operator
If the loop
encloses a surface
, then an explicitly form of the 't Hooft loop operator is
[3]
Using Stokes' theorem this can be rewritten in a way which show that it measures the electric flux through
, analogous to how the Wilson loop measures the magnetic flux through the enclosed surface.
There is a close relation between 't Hooft and Wilson loops where given a two loops
and
that have linking number
, then the 't Hooft loop
and Wilson loop
satisfy
where
is an element of the
center of the gauge group. This relation can be taken as a defining feature of 't Hooft loops. The commutation properties between these two loop operators is often utilized in
topological field theory where these operators form an
algebra.
Disorder operator
The 't Hooft loop is a disorder operator since it creates singularities in the gauge field, with their expectation value distinguishing the disordered phase of pure Yang–Mills theory from the ordered confining phase. Similarly to the Wilson loop, the expectation value of the 't Hooft loop can follow either the area law[4]
\langleT[C]\rangle\sime-a,
where
is the area enclosed by loop
and
is a constant, or it can follow the perimeter law
\langleT[C]\rangle\sime-bL[C],
where
is the length of the loop and
is a constant.
On the basis of the commutation relation between the 't Hooft and Wilson loops, four phases can be identified for
gauge theories that additionally contain
scalars in representations invariant under the center
symmetry. The four phases are
- Confinement: Wilson loops follow the area law while 't Hooft loops follow the perimeter law.
- Higgs phase: Wilson loops follow the perimeter law while 't Hooft loops follow the area law.
- Confinement together with a partially Higgsed phase: both follow the area law.
- Mixed phase: both follow the perimeter law.
In the third phase the gauge group is only partially broken down to a smaller non-abelian subgroup. The mixed phase requires the gauge bosons to be massless particles and does not occur for
theories, but is similar to the Coulomb phase for
abelian gauge theory.
Since 't Hooft operators are creation operators for center vortices, they play an important role in the center vortex scenario for confinement.[5] In this model, it is these vortices that lead to the area law of the Wilson loop through the random fluctuations in the number of topologically linked vortices.
Charge constraints
In the presence of both 't Hooft lines and Wilson lines, a theory requires consistency conditions similar to the Dirac quantization condition which arises when both electric and magnetic monopoles are present.[6] For a gauge group
where
is the
universal covering group with a Lie algebra
and
is a subgroup of the center, then the set of allowed Wilson lines is in
one-to-one correspondence with the
representations of
. This can be formulated more precisely by introducing the
weights
of the Lie algebra, which span the weight lattice
. Denoting
as the lattice spanned by the weights associated with the algebra of
rather than
, the Wilson lines are in one-to-one correspondence with the lattice points
lattice where
is the Weyl group.
The Lie algebra valued charge of the 't Hooft line can always be written in terms of the rank
Cartan subalgebra
as
Q=\boldsymbolm ⋅ \boldsymbolH
, where
is an
-dimensional charge vector. Due to Wilson lines, the 't Hooft charge must satisfy the generalized Dirac quantization condition
, which must hold for all representations of the Lie algebra.
The generalized quantization condition is equivalent to the demand that
\boldsymbolm ⋅ \boldsymbol\mu\in2\piZ
holds for all weight vectors. To get the set of vectors
that satisfy this condition, one must consider
roots
which are
adjoint representation weight vectors. Co-roots, defined using roots by
\boldsymbol\alpha\vee=2\boldsymbol\alpha/\boldsymbol\alpha2
, span the co-root lattice
. These vectors have the useful property that
\boldsymbol\alpha\vee ⋅ \boldsymbol\mu\inZ
meaning that the only magnetic charges allowed for the 't Hooft lines are ones that are in the co-root lattice
\boldsymbolm\in2\piΛco-root(akg).
of
with a weight lattice
, in which case the 't Hooft lines are described by
.
More general classes of dyonic line operators, with both electric and magnetic charges, can also be constructed. Sometimes called Wilson–'t Hooft line operators, they are defined by pairs of charges
up to the
identification that for all
it holds that
Line operators play a role in indicating differences in gauge theories of the form
that differ by the center subgroup
. Unless they are
compactified, these theories do not differ in local physics and no amount of local
experiments can deduce the exact gauge group of the theory. Despite this, the theories do differ in their global properties, such as having different sets of allowed line operators. For example, in
gauge theories, Wilson loops are labelled by
while 't Hooft lines by
. However in
the lattices are reversed where now the Wilson lines are determined by
while the 't Hooft lines are determined by
.
[7] See also
Notes and References
- 't Hooft. G.. Gerard 't Hooft. 1978. On the phase transition towards permanent quark confinement. Nuclear Physics B. 138. 1. 1–25. 10.1016/0550-3213(78)90153-0. 1978NuPhB.138....1T .
- Book: Năstase, H.. Horațiu Năstase. 2019. Introduction to Quantum Field Theory. Cambridge University Press. 50. 472–474. 978-1108493994.
- Reinhardt. H.. 2002. On 't Hooft's loop operator. Phys. Lett. B. 557. 3–4. 317–323. 10.1016/S0370-2693(03)00199-0. hep-th/0212264. 119533753.
- Book: Greensite, J.. 2020. An Introduction to the Confinement Problem. 2. Springer. 4. 43–47. 978-3030515621.
- Englehardt. M.. etal. 1998. Interaction of confining vortices in SU(2) lattice gauge theory. Phys. Lett. B. 431. 1–2. 141–146. 10.1016/S0370-2693(98)00583-8. hep-lat/9801030. 1998PhLB..431..141E . 16961390.
- Ofer. A.. Seiberg. N.. Nathan Seiberg. Tachikawa. Yuji. 2013. Reading between the lines of four-dimensional gauge theories. JHEP. 2013. 8. 115. 10.1007/JHEP08(2013)115. 1305.0318. 2013JHEP...08..115A . 118572353.
- Kapustin. A.. Anton Kapustin. 2006. Wilson-'t Hooft operators in four-dimensional gauge theories and S-duality. Phys. Rev. D. 74. 2. 25005. 10.1103/PhysRevD.74.025005. hep-th/0501015. 2006PhRvD..74b5005K . 17774689.