Existence of locally maximally entangled quantum states via geometric invariant theory

Abstract

We study a question which has natural interpretations in both quantum mechanics and in geometry. Let V1,..., Vn be complex vector spaces of dimension d1,...,dn and let G= SLd1 × … × SLdn. Geometrically, we ask given (d1,...,dn), when is the geometric invariant theory quotient P(V1 … Vn)// G non-empty? This is equivalent to the quantum mechanical question of whether the multipart quantum system with Hilbert space V1 … Vn has a locally maximally entangled state, i.e. a state such that the density matrix for each elementary subsystem is a multiple of the identity. We show that the answer to this question is yes if and only if R(d1,...,dn)≥slant 0 where \[ R(d1,...,dn) = Πi di +Σk=1n (-1)k Σ1≤ i1<…b <ik≤ n ((di1,…c ,dik) )2. \] We also provide a simple recursive algorithm which determines the answer to the question, and we compute the dimension of the resulting quotient in the non-empty cases.