Reduction of quantum systems and the local Gauss law
Ruben Stienstra, Walter D. van Suijlekom

TL;DR
This paper provides an operator-algebraic framework for understanding ideals generated by unbounded operators in quantum systems, linking Rieffel induction to local Gauss laws in lattice gauge theories.
Contribution
It introduces a novel operator-algebraic interpretation of ideals related to Lie algebra elements, connecting Rieffel induction with local Gauss law implementation in lattice gauge theories.
Findings
Established a link between Rieffel induction and local Gauss law implementation.
Provided an operator-algebraic interpretation of ideals generated by Lie algebra operators.
Applied the framework to lattice gauge theories.
Abstract
We give an operator-algebraic interpretation of the notion of an ideal generated by the unbounded operators associated to the elements of the Lie algebra of a Lie group that implements the symmetries of a quantum system. We use this interpretation to establish a link between Rieffel induction and the implementation of a local Gauss law in lattice gauge theories similar to the method discussed by Kijowski and Rudolph in [5, 6].
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Reduction of quantum systems
and the local Gauss law
Ruben Stienstra
and
Walter D. van Suijlekom
Institute for Mathematics, Astrophysics and Particle Physics, Radboud University Nijmegen, Heyendaalseweg 135, 6525 AJ Nijmegen, The Netherlands
[email protected], [email protected]
Abstract.
We give an operator-algebraic interpretation of the notion of an ideal generated by the unbounded operators associated to the elements of the Lie algebra of a Lie group that implements the symmetries of a quantum system. We use this interpretation to establish a link between Rieffel induction and the implementation of a local Gauss law in lattice gauge theories similar to the method discussed by Kijowski and Rudolph in [5, 6].
Key words and phrases:
quantum symmetry reduction, unbounded operators
2010 Mathematics Subject Classification:
22E70, 46N50, 81R15
1. Introduction
There are well-developed theories of reduction of both classical and quantum mechanical systems that possess symmetries. The study of reduction of classical systems was initiated by Dirac in [2] with his theory of first and second order constraints, and later put into the language of symplectic manifolds by Arnold and Smale. The reduction of a symplectic manifold with respect to an equivariant moment map was described by Marsden and Weinstein in their paper [9]. For a more detailed account of the history of symplectic reduction, we refer to [10] and references therein. A procedure known as Rieffel induction, developed in [12], appears to be a good candidate for a quantum version of Marsden–Weinstein reduction [7] (cf. [8, IV.2]).
The primary aim of this paper is to compare two different ways to reduce the quantum mechanical observable algebra. The first one is the method of Rieffel induction mentioned above. The second one was outlined by Kijowski and Rudolph in [5, 6] in the context of a quantum lattice gauge theory, in which they explicitly implement a constraint, the local Gauss law, by ensuring that the operators associated to the generators of the gauge group vanish in the observable algebra of the reduced system. The corresponding operators on the unreduced Hilbert space are unbounded, however, which requires them to appeal to the theory of C∗-algebras generated by unbounded operators as developed by Woronowicz in [15], something that is not necessary for Rieffel induction. Nevertheless, both procedures yield the same reduced observable algebra. In this paper, we modify the latter method so that it is formulated entirely in terms of bounded operators, and show that it agrees with the final step in the process of Rieffel induction.
The paper is organised as follows. In Section 2, we briefly recall the process of Rieffel induction. In Section 3, we formulate and prove the main theorem that establishes the link. In Section 4, we discuss some examples, including the lattice gauge theory mentioned above.
Acknowledgements
We would like to thank Francesca Arici, Klaas Landsman and Gerd Rudolph for useful comments and helpful discussions. This research was partially supported by NWO under the VIDI-grant 016.133.326.
2. Reduction of quantum systems using Rieffel induction
The kinematical data of a quantum system consists of a Hilbert space and a faithful representation of a C∗-algebra on . A continuous symmetry of a quantum system typically (but, in accordance with Wigner’s celebrated theorem, not exclusively,) corresponds to a continuous unitary representation of some Lie group on . We are interested in studying the reduction of the kinematical data with respect to such symmetries in the case in which is compact. A systematic way to obtain this reduction, known as Rieffel induction, was proposed by Landsman in [7] using an induction procedure for representations of C∗-algebras developed by Rieffel in [12].
Let us first briefly recall the process of Rieffel induction. Starting from the above representation of the group , one endows with the structure of a right Hilbert -module, where denotes the group C∗-algebra of . Subsequently, one takes the quotient of with respect to the null space of a bilinear form on , which yields a space naturally isomorphic to , the subspace of of -invariant elements. Thus we obtain the Hilbert space of the reduced system.
At the level of the observable algebra, one first considers the algebra of elements of that are equivariant with respect to the given unitary representation. The space is invariant under these observables, yielding a representation of the C∗-algebra on . The image of this representation is isomorphic to , and hence one obtains a faithful representation of on , which forms the remaining part of the kinematical data of the reduced system.
Motivated by the theory of strict quantization of observable algebras as described extensively in [8, Part II], we are interested in the case where , the space of compact operators, and its representation on is the obvious one. It can then be shown that is isomorphic to , and that the representation of this algebra on the reduced Hilbert space is again the obvious one.
3. Associating algebras to infinitesimal generators
The main purpose of this section is to discuss a possible interpretation of an observation made by Kijowski and Rudolph in [6, Section 3] in the case of a quantum lattice gauge theory, namely that the kernel of the representation , where as before , is in some sense generated by the elements of the Lie algebra of the symmetry group . The representation of the group on can be used to associate differential operators to the elements of , which are typically unbounded if is infinite-dimensional. If instead the representation space is finite-dimensional then the representation of the Lie algebra is bounded. Using this fact and other standard results from the representation theory of Lie groups, we will show how the differential operators associated to the elements of the Lie algebra generate . In addition, we need the following preparatory lemma, which can be found in [11, Exercise 4.2(c)]:
Lemma 1**.**
Let be a Hilbert space, let be a compact operator on , and suppose that is a bounded net of bounded operators that converges strongly to . Then the net converges in norm to . If in addition the operator is hermitian for each , then the net converges in norm to .
The following result shows how can be generated by differential operators:
Theorem 2**.**
Suppose is a compact, connected Lie group. Let be a collection of finite-dimensional subrepresentations of the continuous representation , and for each , let be the subspace on which is represented. Suppose that these representation spaces form an orthogonal decomposition of , i.e.,
[TABLE]
Then is the closed, two-sided ideal generated by the set
[TABLE]
Remark 3**.**
In the set of generators above, is regarded as the compression of to . Moreover, we note that the integrals of vector-valued functions can be defined using Bochner integration.
Proof of Theorem 1..
Let be the ideal in generated by the set in equation (1). We first show that . Indeed, maps into for each , each and each , hence so does , which implies that it is a finite rank operator. In particular, it is compact. Moreover, it follows from left invariance of the Haar measure that is equivariant with respect to , so it is an element of . Finally, to show that it is an element of , let be the orthogonal projection onto the representation space of . For each we have and . Hence
[TABLE]
and therefore . Thus the generators of are contained in . Since is a closed, two sided ideal, it follows that .
We turn to the proof of the reverse inclusion. Let , let be the orthogonal projection of onto . It is easy to see that
[TABLE]
Since , it follows that
[TABLE]
By the preceding lemma, the series on the right-hand side is norm-convergent, hence to show that , it suffices to show that
[TABLE]
for each . Since is closed under multiplication with elements of , we are done if we can show that
[TABLE]
From bi-invariance of the Haar measure and Fubini’s theorem, we infer that
[TABLE]
The norm topology and the strong topology coincide on the finite-dimensional algebra , so the first integral on the right-hand side is a norm limit of Riemann sums, i.e. for each , there exist and for , such that
[TABLE]
Since is closed by definition, it suffices to show that
[TABLE]
We prove this by showing that
[TABLE]
for each . Now fix such a . Because is both compact and connected, the exponential map is surjective, so there exists an such that . But is a homomorphism of Lie groups, so
[TABLE]
Thus
[TABLE]
The map
[TABLE]
is a linear operator on the finite-dimensional algebra , hence it is norm-continuous, so
[TABLE]
and the series on the right-hand side converges with respect to the norm on . Each of the partial sums is an element of , which implies that ( ‣ 3) holds, as desired. ∎
In general, the set in the above theorem will not be unique. Suppose that we are in the situation of the theorem, and that we are given a set satisfying the assumption. If the Hilbert space is infinite-dimensional, there are infinitely many different sets like that satisfy the assumption. Indeed, is an infinite set because is infinite-dimensional, so we can take any finite subset containing at least two representations, define the subrepresentation , and the set . Then , and it satisfies the assumption of the theorem.
The last argument can be formulated slightly more generally as follows: Suppose that and are sets of orthogonal finite-dimensional subrepresentations, and that satisfies the assumption of the theorem. If each element of is a subrepresentation of , then also satisfies the assumption. If is infinite-dimensional, then from any set one can always construct a different set with these properties. Thus one can always make the set ‘arbitrarily coarse’, which is another reason why we view Theorem 1 as a possible way to make the idea of ‘the ideal generated by unbounded operators’ rigorous.
The fact that a set like the one in Theorem 1 always exists, is a consequence of the following result. Recall that for any representation of a group on a space , a vector is called -finite if and only if the smallest subspace containing that is invariant under , i.e., the span of , is finite-dimensional. We let denote the subspace of -finite vectors of .
Proposition 4**.**
Let be a continuous representation of a compact Lie group in a complete locally convex topological vector space . Then is dense in .
This result can be found in [3] as part of Corollary 4.6.3. Using this result and Zorn’s lemma, one can now readily show that there exists a set which satisfies the assumption of our theorem. Needless to say, explicitly exhibiting such a set might be impossible. However, as we shall see in the next section, there are situations in which there is a natural choice for .
Before we end this section, we briefly recall some other notions from representation theory. Let be the set of equivalence classes of irreducible representations of , and let . The isotypical component of type is the set of elements such that the subrepresentation generated by is equivalent to the representation ( copies) for some .
4. Examples
4.1. Local Gauss law in quantum lattice gauge theories
We start with the motivating example for this paper, namely the local Gauss law discussed by Kijowski and Rudolph in [6] in the context of quantum lattice gauge theories. Let be a finite, connected, oriented graph whose sets of vertices and edges are given by and , respectively. Moreover, let be the maps that assign to an edge its source and target, respectively. Finally, let be a compact Lie group. Let , and let be the sets of functions from and to , respectively. In lattice gauge theory, is the gauge group, while is the space of connections. We endow these sets of functions with Lie group structures simply by viewing them as direct products of with itself. Then carries an action of , which is given by
[TABLE]
This action induces a continuous unitary representation of on by , where , and .
Baez already noted in [1] that the action of restricts to the isotypical components of with respect to the left regular representation of on this space —in fact, these isotypical components form the basis for spin networks as introduced in [13]. Indeed, the representation can be regarded as the composition of two group homomorphisms; first, we have a homomorphism
[TABLE]
which by connectedness of the graph is an injection if and only if has more than one vertex. The second homomorphism is the product representation of the left and right regular representations and , respectively. It follows that each subspace of that is invariant under the representation , is also invariant under . The Peter–Weyl theorem asserts that
[TABLE]
and that the isotypical components are irreducible subrepresentations of the representation of dimension . Here, denotes the set of -finite vectors with respect to the left regular representation of on . Thus we may take the set in Theorem 1 to be the collection of subrepresentations obtained by restricting to for each .
Since the elements of the Lie algebra of the gauge group generate the gauge group, Theorem 1 provides a link between two different methods of reduction of the quantum observable algebra, the first being Rieffel induction, and the second being the implementation of a local Gauss law by taking the quotient with respect to an ideal generated by unbounded operators associated to Lie algebra elements, as mentioned by Kijowski and Rudolph in [6].
4.2. Hamiltonian symmetries
The second example that we discuss is really more of a class of examples, namely that of quantum systems with a given Hamiltonian that possesses a certain symmetry.
Let be a Hilbert space, let be a (possibly unbounded) self-adjoint operator on , and suppose is a continuous unitary representation of a compact connected Lie group on with the property that preserves and for each . Moreover, let be the point spectrum of , and for each , let be the eigenspace corresponding to . Suppose that is finite dimensional for each , and that . Then restricts to a representation on for each , and we may set .
A notable subclass of examples satisfying the above conditions is the class of quantum systems in which , where is a compact smooth Riemannian manifold that admits a Lie group of isometries, and is the Laplacian on . In particular, the lattice gauge theories in Section 4.1 can be studied in this way if one endows with a bi-invariant Riemannian metric. It is a result from representation theory (cf. [14, Theorem 3.3.5]) that is a subspace of an eigenspace of for each , so the decomposition obtained in the previous example is finer than the decomposition into eigenspaces of .
The reference list from the paper itself. Each links out to its DOI / PubMed record.
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