Nonadditive entropy reconciles the area law in quantum systems with classical thermodynamics

The Boltzmann-Gibbs-von Neumann entropy of a large part (of linear size L ) of some (much larger) d -dimensional quantum systems follows the so-called area law (as for black holes), i.e., it is proportional to L^d-1 . Here we show, for d=1,2 , that the (nonadditive) entropy S_q satisfies, for a special value of q≠1 , the classical thermodynamical prescription for the entropy to be extensive, i.e., S_q∝L^d . Therefore, we reconcile with classical thermodynamics the area law widespread in quantum systems. Recently, a similar behavior was exhibited in mathematical models with scale-invariant correlations [C. Tsallis, M. Gell-Mann, and Y. Sato, Proc. Natl. Acad. Sci. U.S.A.102 15377 (2005)]. Finally, we find that the system critical features are marked by a maximum of the special entropic index q .