Difficulties in analytic computation for relative entropy of entanglement

Abstract

It is known that relative entropy of entanglement for entangled state is defined via its closest separable (or positive partial transpose) state σ. Recently, it has been shown how to find provided that σ is given in two-qubit system. In this paper we study on the inverse process, i.e. how to find σ provided that is given. It is shown that if is one of Bell-diagonal, generalized Vedral-Plenio and generalized Horodecki states, one can always find σ from a geometrical point of view. This is possible due to the following two facts: (i) The Bloch vectors of and σ are identical with each other (ii) The qubit-interaction vector of σ can be computed from a crossing point between minimal geometrical object, in which all separable states reside in the presence of Bloch vectors, and a straight line, which connects the point corresponding to the qubit-interaction vector of and the nearest vertex of the maximal tetrahedron, where all two-qubit states reside. It is shown, however, that these nice properties are not maintained for the arbitrary two-qubit states.