Entanglement can preserve the compact nature of the phase-space occupancy

Abstract

We study the one-dimensional transverse-field spin-1/2 Ising ferromagnet at its critical point. We consider an L-sized subsystem of a N-sized ring, and trace over the states of (N-L) spins, with N∞. The full N-system is in a pure state, but the L-system is in a statistical mixture. As well known, for L >>1, the Boltzmann-Gibbs-von Neumann entropy violates thermodynamical extensivity, namely SBG(L) L, whereas the nonadditive entropy Sq is extensive for q=qc=37-6 , namely Sqc(L) L. When this problem is expressed in terms of independent fermions, we show that the usual thermostatistical sums emerging within Fermi-Dirac statistics can, for L>>1, be indistinctively taken up to L terms or up to L terms. This is interpreted as a compact occupancy of phase-space of the L-system, hence standard BG quantities with an effective length V L are appropriate and are explicitly calculated. In other words, the calculations are to be done in a phase-space whose effective dimension is 2 L instead of 2L. The whole scenario is strongly reminiscent of a usual phase transition of a spin-1/2 d-dimensional system, where the phase-space dimension is 2Ld in the disordered phase, and effectively 2Ld/2 in the ordered one.