Subspace Controllability and Clebsch-Gordan Decomposition of Symmetric Quantum Networks

Abstract

We describe a framework for the controllability analysis of networks of n quantum systems of an arbitrary dimension d, qudits, with dynamics determined by Hamiltonians that are invariant under the permutation group Sn. Because of the symmetry, the underlying Hilbert space, H=(Cd) n, splits into invariant subspaces for the Lie algebra of Sn-invariant elements in u(dn), denoted here by uSn(dn). The dynamical Lie algebra L, which determines the controllability properties of the system, is a Lie subalgebra of such a Lie algebra uSn(dn). If L acts as su( (V) ) on each of the invariant subspaces V, the system is called subspace controllable. Our approach is based on recognizing that such a splitting of the Hilbert space H coincides with the Clebsch-Gordan splitting of (Cd) n into irreducible representations of su(d). In this view, uSn(dn), is the direct sum of certain su(nj) for some nj's we shall specify, and its center which is the Abelian (Lie) algebra generated by the Casimir operators. Generalizing the situation previously considered in the literature, we consider dynamics with arbitrary local simultaneous control on the qudits and a symmetric two body interaction. Most of the results presented are for general n and d but we recast previous results on n qubits in this new general framework and provide a complete treatment and proof of subspace controllability for the new case of n=3, d=3, that is, three qutrits.