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Abstract
The operator Schmidt rank is the minimum number of terms required to express a state as a sum of elementary tensor factors. Here we provide a new proof of the fact that any bipartite mixed state with operator Schmidt rank two is separable, and can be written as a sum of two positive semidefinite matrices per site. Our proof uses results from the theory of free spectrahedra and operator systems, and illustrates the use of a connection between decompositions of quantum states and decompositions of nonnegative matrices. In the multipartite case, we prove that any Hermitian Matrix Product Density Operator (MPDO) of bond dimension two is separable, and can be written as a sum of at most four positive semidefinite matrices per site. This implies that these states can only contain classical correlations, and very few of them, as measured by the entanglement of purification. In contrast, MPDOs of bond dimension three can contain an unbounded amount of classical correlations.
Highlights
Entanglement is an essential ingredient in many applications in quantum information processing and quantum computation [NC00, HHHH09]
We provide an explicit procedure to obtain the separable decomposition of a bipartite state with operator Schmidt rank two
We have shown that any bipartite positive semidefinite matrix of operator Schmidt rank two is separable, and admits a separable decomposition with two positive semidefinite matrices per site (Theorem 1)
Summary
Entanglement is an essential ingredient in many applications in quantum information processing and quantum computation [NC00, HHHH09]. The first main result of this paper is that, if a state has operator Schmidt rank two, it is separable It can be written as a sum of only two positive semidefinite matrices at each site. The second main result of this paper is that if a multipartite state has Hermitian operator Schmidt rank two, it is separable. It admits a separable decomposition of bond dimension two, which means that it can be written as a sum of at most four positive semidefinite matrices per site.
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