A quantum system (with Hilbert space ) entangled with its environment (with Hilbert space ) is usually not attributed to a wave function but only to a reduced density matrix . Nevertheless, there is a precise way of attributing to it a random wave function , called its conditional wave function, whose probability distribution depends on the entangled wave function in the Hilbert space of system and environment together. It also depends on a choice of orthonormal basis of but in relevant cases, as we show, not very much. We prove several universality (or typicality) results about , e.g., that if the environment is sufficiently large then for every orthonormal basis of , most entangled states with given reduced density matrix are such that is close to one of the so-called GAP (Gaussian adjusted projected) measures, . We also show that, for most entangled states from a microcanonical subspace (spanned by the eigenvectors of the Hamiltonian with energies in a narrow interval ) and most orthonormal bases of , is close to with the normalized projection to the microcanonical subspace. In particular, if the coupling between the system and the environment is weak, then is close to with the canonical density matrix on at inverse temperature . This provides the mathematical justification of our claim in Goldstein et al. (J Stat Phys 125: 1193-1221, 2006) that GAP measures describe the thermal equilibrium distribution of the wave function.

• 出版日期2016-3
• 单位rutgers