Reexamination of strong subadditivity: A quantum-correlation approach

Abstract

The strong subadditivity inequality of von Neumann entropy relates the entropy of subsystems of a tripartite state ABC to that of the composite system. Here, we define T(a)(ABC) as the extent to which ABC fails to satisfy the strong subadditivity inequality S(B)+S(C) S(AB)+S(AC) with equality and investigate its properties. In particular, by introducing auxiliary subsystem E, we consider any purification |ABCE of ABC and formulate T(a)(ABC) as the extent to which the bipartite quantum correlations of AB and AC, measured by entanglement of formation and quantum discord, change under the transformation B→ BE and C→ CE. Invariance of quantum correlations of AB and AC under such transformation is shown to be a necessary and sufficient condition for vanishing T(a)(ABC). Our approach allows one to characterize, intuitively, the structure of states for which the strong subadditivity is saturated. Moreover, along with providing a conservation law for quantum correlations of states for which the strong subadditivity inequality is satisfied with equality, we find that such states coincides with those that the Koashi-Winter monogamy relation is saturated.