Attempts have been made to describe gauge theories in terms of extended objects such as Wilson loops and holonomies. The loop representation is a quantum hamiltonian representation of gauge theories in terms of loops. The aim of the loop representation in the context of Yang–Mills theories is to avoid the redundancy introduced by Gauss gauge symmetries allowing to work directly in the space of physical states (Gauss gauge invariant states). The idea is well known in the context of lattice Yang–Mills theory (see lattice gauge theory). Attempts to explore the continuous loop representation was made by Gambini and Trias for canonical Yang–Mills theory, however there were difficulties as they represented singular objects. As we shall see the loop formalism goes far beyond a simple gauge invariant description, in fact it is the natural geometrical framework to treat gauge theories and quantum gravity in terms of their fundamental physical excitations.
The introduction by Ashtekar of a new set of variables (Ashtekar variables) cast general relativity in the same language as gauge theories and allowed one to apply loop techniques as a natural nonperturbative description of Einstein's theory. In canonical quantum gravity the difficulties in using the continuous loop representation are cured by the spatial diffeomorphism invariance of general relativity. The loop representation also provides a natural solution of the spatial diffeomorphism constraint, making a connection between canonical quantum gravity and knot theory. Surprisingly there were a class of loop states that provided exact (if only formal) solutions to Ashtekar's original (ill-defined) Wheeler–DeWitt equation. Hence an infinite set of exact (if only formal) solutions had been identified for all the equations of canonical quantum general gravity in this representation! This generated a lot of interest in the approach and eventually led to loop quantum gravity (LQG).
The loop representation has found application in mathematics. If topological quantum field theories are formulated in terms of loops, the resulting quantities should be what are known as knot invariants. Topological field theories only involve a finite number of degrees of freedom and so are exactly solvable. As a result, they provide concrete computable expressions that are invariants of knots. This was precisely the insight of Edward Witten[1] who noticed that computing loop dependent quantities in Chern–Simons and other three-dimensional topological quantum field theories one could come up with explicit, analytic expressions for knot invariants. For his work in this, in 1990 he was awarded the Fields Medal. He is the first and so far the only physicist to be awarded the Fields Medal, often viewed as the greatest honour in mathematics.
The idea of gauge symmetries was introduced in Maxwell's theory. Maxwell's equations are
\nabla ⋅ \vec{E}={\rho\over\epsilon0} \nabla x \vec{B}-\epsilon0\mu0{\partial\vec{E}\over\partialt}=\mu0\vec{J} \nabla x \vec{E}+{\partial\vec{B}\over\partialt}=0 \nabla ⋅ \vec{B}=0
where
\rho
\vec{J}
\phi
\vec{A}
\vec{E}=-\nabla\phi-{\partial\vec{A}\over\partialt} \vec{B}=\nabla x \vec{A}
The potentials uniquely determine the fields, but the fields do not uniquely determine the potentials - we can make the changes:
\phi'=\phi+{\partialΛ\over\partialt} \vec{A}'=\vec{A}-\nablaΛ
without affecting the electric and magnetic fields, where
Λ(\vec{x},t)
A\mu=(\phi,\vec{A})
and the above gauge transformations read,
{A\mu}'=A\mu+\partial\muΛ
The so-called field strength tensor is introduced,
F\mu=\partial\muA\nu-\partial\nuA\mu
which is easily shown to be invariant under gauge transformations. In components,
F0i=Ei, \epsilonijkFjk=Bi
Maxwell's source-free action is given by:
S=-{1\over2}\intd4x(F\muF\mu)
The ability to vary the gauge potential at different points in space and time (by changing
Λ(\vec{x},t)
U(1)
We know from quantum mechanics that if we replace the wave-function,
\psi(x)
\psi'(x)=\exp(i\theta)\psi(x)
that it leaves physical predictions unchanged. We consider the imposition of local invariance on the phase of the electron field,
\psi'(x)=\Omega\psi(x)=\exp(i\theta(x))\psi(x)
The problem is that derivatives of
\psi(x)
\partial\mu(\exp(i\theta(x))\psi(x))=\Omega\partial\mu\psi(x)+\partial\mu\Omega\psi(x)
In order to cancel out the second unwanted term, one introduces a new derivative operator
l{D}\mu
l{D}\mu
A\mu
l{D}\mu=\partial\mu+igA\mu(x)
Then
(l{D}\mu\psi)'=\partial\mu\psi'+igA\mu'\psi'=\Omega\partial\mu\psi+(\partial\Omega)\psi+igA\mu'\Omega\psi
The term
\partial\mu\Omega
A\mu'(x)=A\mu(x)+{i\overg}[\partial\mu\Omega(x)]\Omega-1(x) Eq1.
We then have that
(l{D}\mu\psi)'=\Omegal{D}\mu\psi
Note that
Eq1
A\mu'(x)=A\mu(x)+{1\overg}\partial\mu\theta(x)
which looks the same as a gauge transformation of the gauge potential of Maxwell's theory. It is possible to construct an invariant action for the connection field itself. We want an action that only has two derivatives (since actions with higher derivatives are not unitary). Define the quantity:
F\mu={-i\overg}[l{D}\mu,l{D}\mu]={-i\overg}[\partial\mu+igA\mu(x),\partial\nu+igA\nu(x)]
={-i\overg}([\partial\mu,\partial\nu]+ig(\partial\muA\nu-\partial\nuA\mu)-g2[A\mu,A\nu])
=\partial\muA\nu-\partial\nuA\nu
The unique action with only two derivatives is given by:
S=-
1 | |
2 |
\intd4x(F\muF\mu)
Therefore, one can derive electromagnetic theory from arguments based solely on symmetry.
We now generalize the above reasoning to general gauge groups. One begins with the generators of some Lie algebra:
[Ti,Tj]=ifijkTk
Let there be a fermion field that transforms as
\Psi'\mapsto\hat{\Omega}(x)\Psi(x)=\exp(i\thetai(x)Ti)\Psi(x)
Again the derivatives of
\Psi(x)
l{D
with connection field given by
A\mu(x)=
i | |
A | |
\mu |
(x)Ti
We require that
A\mu(x)
A\mu'(x)=\hat{\Omega}A\mu(x)\hat{\Omega}-1+{i\overg}\hat{\Omega}(\partial\mu\hat{\Omega}-1)
We define the field strength operator
F\mu=-{i\overg}[l{D
As
l{D
i | |
F | |
\mu\nu |
F\mu\mapstoF\mu'=\hat{\Omega}F\mu\hat{\Omega}-1
Note that
F\mu
\hat{\Omega}
We can now construct an invariant action out of this tensor. Again we want an action that only has two derivatives. The simplest choice is the trace of the commutator:
\operatorname{Tr}(\hat{\Omega}F\mu\hat{\Omega}-1\hat{\Omega}F\mu\hat{\Omega}-1)=\operatorname{Tr}(F\muF\mu)
The unique action with only two derivatives is given by:
S=-{1\over2}\intd4xTr(F\muF\mu)=-{1\over2}\intd4x\operatorname{Tr}(
i | |
F | |
\mu\nu |
Tj
\mu\nu | |
F | |
j |
Tj)
This is the action for Yang-mills theory.
We consider a change of representation in the quantum Maxwell gauge theory. The idea is to introduce a basis of states labeled by loops
\mid\gamma\rangle
\langleA\mid\gamma\rangle=W(\gamma)=\exp\left[ie\int\gammady\alphaA\alpha(y)\right]
The loop functional
W(\gamma)
U(1)
We consider for simplicity (and because later we will see this is the relevant gauge group in LQG) an
SU(2)
SU(2)
i | |
A | |
\mu |
(x)
i
SU(2)
A\mu(x)=
i | |
A | |
\mu |
(x)\taui
where
\taui
su(2)
i/2
A\mu(x)
SU(2)
We first describe the quantum theory in terms of connection variable.
In the connection representation the configuration variable is
i | |
A | |
a |
a | |
\tilde{E} | |
i |
\Psi
i) | |
(A | |
a |
i | |
\hat{A} | |
a |
\Psi[A]=
i | |
A | |
a |
\Psi[A]
(analogous to the position representation
\hat{q}\psi(q)=q\psi(q)
i | |
\hat{\tilde{E}} | |
a |
\Psi[A]=-i{\delta\Psi[A]\over\delta
i} | |
A | |
a |
(analogous to
\hat{p}\psi(q)=-i{d\psi(q)\overdq}
Let us return to the classical Yang–Mills theory. It is possible to encode the gauge invariant information of the theory in terms of `loop-like' variables.
We need the notion of a holonomy. A holonomy is a measure of how much the initial and final values of a spinor or vector differ after parallel transport around a closed loop
\gamma
h\gamma[A]
Knowledge of the holonomies is equivalent to knowledge of the connection, up to gauge equivalence. Holonomies can also be associated with an edge; under a Gauss Law these transform as
(h'e)\alpha=
-1 | |
U | |
\alpha\gamma |
(x)(he)\gammaU\sigma(y).
For a closed loop
x=y
\alpha=\beta
(h'e)\alpha=
-1 | |
U | |
\alpha\gamma |
(x)(he)\gammaU\sigma(x)=[U\sigma(x)
-1 | |
U | |
\alpha\gamma |
(x)](he)\gamma=\delta\sigma(he)\gamma=(he)\gamma
or
\operatorname{Tr}h'\gamma=\operatorname{Tr}h\gamma.
Thus the trace of an holonomy around a closed loop is gauge invariant. It is denoted
W\gamma[A]
and is called a Wilson loop. The explicit form of the holonomy is
h\gamma[A]=l{P}\exp\{-
\gamma1 | |
\int | |
\gamma0 |
ds
\gamma |
a
i | |
A | |
a |
(\gamma(s))Ti\}
where
\gamma
s
l{P}
s
Ti
su(2)
[Ti,Tj]=2i\epsilonijkTk.
The Pauli matrices satisfy the above relation. It turns out that there are infinitely many more examples of sets of matrices that satisfy these relations, where each set comprises
(N+1) x (N+1)
N=1,2,3,...
su(2)
N/2
An important theorem about Yang–Mills gauge theories is Giles' theorem, according to which if one gives the trace of the holonomy of a connection for all possible loops on a manifold one can, in principle, reconstruct all the gauge invariant information of the connection.[2] That is, Wilson loops constitute a basis of gauge invariant functions of the connection. This key result is the basis for the loop representation for gauge theories and gravity.
The use of Wilson loops explicitly solves the Gauss gauge constraint. As Wilson loops form a basis we can formally expand any Gauss gauge invariant function as,
\Psi[A]=\sum\gamma\Psi[\gamma]W\gamma[A]
This is called the loop transform. We can see the analogy with going to the momentum representation in quantum mechanics. There one has a basis of states
\exp(ikx)
k
\psi[x]=\intdk\psi(k)\exp(ikx).
and works with the coefficients of the expansion
\psi(k)
The inverse loop transform is defined by
\Psi[\gamma]=\int[dA]\Psi[A]W\gamma[A].
This defines the loop representation. Given an operator
\hat{O}
\Phi[A]=\hat{O}\Psi[A], Eq1
one should define the corresponding operator
\hat{O}'
\Psi[\gamma]
\Phi[\gamma]=\hat{O}'\Psi[\gamma], Eq2
where
\Phi[\gamma]
\Phi[\gamma]=\int[dA]\Phi[A]W\gamma[A]. Eq3
A transformation formula giving the action of the operator
\hat{O}'
\Psi[\gamma]
\hat{O}
\Psi[A]
Eq 2
Eq 3
Eq 1
Eq 3
\hat{O}'\Psi[\gamma]=\int[dA]W\gamma[A]\hat{O}\Psi[A],
or
\hat{O}'\Psi[\gamma]=\int[dA](\hat{O}\daggerW\gamma[A])\Psi[A],
where by
\hat{O}\dagger
\hat{O}
\Psi[A]
See main article: Holonomy, Wilson loop and Knot invariant.
The introduction of Ashtekar variables cast general relativity in the same language as gauge theories. It was in particular the inability to have good control over the space of solutions to the Gauss' law and spatial diffeomorphism constraints that led Rovelli and Smolin to consider a new representation – the loop representation.[3]
To handle the spatial diffeomorphism constraint we need to go over to the loop representation. The above reasoning gives the physical meaning of the operator
\hat{O}'
\hat{O}\dagger
A
W\gamma[A]
\gamma
\hat{O}'
\gamma
\Psi[\gamma]
In the loop representation we can then solve the spatial diffeomorphism constraint by considering functions of loops
\Psi[\gamma]
\gamma
The easiest geometric quantity is the area. Let us choose coordinates so that the surface
\Sigma
x3=0
\Sigma
\sin\theta
\theta
\vec{u}
\vec{v}
\begin{align} A&=\|\vec{u}\|\|\vec{v}\|\sin\theta=\sqrt{\|\vec{u}\|2\|\vec{v}\|2(1-\cos2\theta)}\\[6pt] &=\sqrt{\|\vec{u}\|2\|\vec{v}\|2-(\vec{u} ⋅ \vec{v})2} \end{align}
From this we get the area of the surface
\Sigma
A\Sigma=\int\Sigmadx1dx2\sqrt{\det q(2)
where
\detq(2)=q11q22-
2 | |
q | |
12 |
\Sigma
\det q(2)={\epsilon3ab\epsilon3cdqacqbc\over2}.
The standard formula for an inverse matrix is
qab={\epsilonbcd\epsilonaefqceqdf\over2!\det(q)}
Note the similarity between this and the expression for
\detq(2)
a | |
\tilde{E} | |
i |
\tilde{E}bi=\det(q)qab
A\Sigma=\int\Sigmadx1dx2
3 | |
\sqrt{\tilde{E} | |
i |
\tilde{E}3i
According to the rules of canonical quantization we should promote the triads
3 | |
\tilde{E} | |
i |
3 | |
\hat{\tilde{E}} | |
i |
\sim{\delta\over\delta
i}. | |
A | |
3 |
It turns out that the area
A\Sigma
N=2J
\sumiTiTi=J(J+1)1
\hat{A}\SigmaW\gamma[A]=8\pi
2 | |
\ell | |
Planck |
\beta\sumI\sqrt{jI(jI+1)}W\gamma[A]
where the sum is over all edges
I
\Sigma
The formula for the volume of a region
R
V=\intRd3x\sqrt{\det(q)}={1\over6}\intRdx3\sqrt{\epsilonabc\epsilonijk
a | |
\tilde{E} | |
i |
b | |
\tilde{E} | |
j |
c | |
\tilde{E} | |
k}. |
The quantization of the volume proceeds the same way as with the area. As we take the derivative, and each time we do so we bring down the tangent vector
\gamma |
a
We now consider Wilson loops with intersections. We assume the real representation where the gauge group is
SU(2)
SU(2)
A
B
\operatorname{Tr}(A)\operatorname{Tr}(B)=\operatorname{Tr}(AB)+\operatorname{Tr}(AB-1).
This implies that given two loops
\gamma
η
W\gamma[A]Wη[A]=W\gamma[A]+
W | |
\gamma\circη-1 |
[A]
where by
η-1
η
\gamma\circη
\gamma
η
W(\gamma1\circ\gamma2)=W(\gamma2\circ\gamma1)
In fact spin networks constitute a basis for all gauge invariant functions which minimize the degree of over-completeness of the loop basis, and for trivalent intersections eliminate it entirely.
As mentioned above the holonomy tells you how to propagate test spin half particles. A spin network state assigns an amplitude to a set of spin half particles tracing out a path in space, merging and splitting. These are described by spin networks
\gamma
Theorems establishing the uniqueness of the loop representation as defined by Ashtekar et al. (i.e. a certain concrete realization of a Hilbert space and associated operators reproducing the correct loop algebra – the realization that everybody was using) have been given by two groups (Lewandowski, Okolow, Sahlmann and Thiemann)[5] and (Christian Fleischhack).[6] Before this result was established it was not known whether there could be other examples of Hilbert spaces with operators invoking the same loop algebra, other realizations, not equivalent to the one that had been used so far.
A common method of describing a knot (or link, which are knots of several components entangled with each other) is to consider its projected image onto a plane called a knot diagram. Any given knot (or link) can be drawn in many different ways using a knot diagram. Therefore, a fundamental problem in knot theory is determining when two descriptions represent the same knot. Given a knot diagram, one tries to find a way to assign a knot invariant to it, sometimes a polynomial – called a knot polynomial. Two knot diagrams with different polynomials generated by the same procedure necessarily correspond to different knots. However, if the polynomials are the same, it may not mean that they correspond to the same knot. The better a polynomial is at distinguishing knots the more powerful it is.
In 1984, Jones [7] announced the discovery of a new link invariant, which soon led to a bewildering profusion of generalizations. He had found a new knot polynomial, the Jones polynomial. Specifically, it is an invariant of an oriented knot or link which assigns to each oriented knot or link a polynomial with integer coefficients.
In the late 1980s, Witten coined the term topological quantum field theory for a certain type of physical theory in which the expectation values of observable quantities are invariant under diffeomorphisms.
Witten [8] gave a heuristic derivation of the Jones polynomial and its generalizations from Chern–Simons theory. The basic idea is simply that the vacuum expectation values of Wilson loops in Chern–Simons theory are link invariants because of the diffeomorphism-invariance of the theory. To calculate these expectation values, however, Witten needed to use the relation between Chern–Simons theory and a conformal field theory known as the Wess–Zumino–Witten model (or the WZW model).