Time Evolution of Typical Pure States from a Macroscopic Hilbert Subspace

Abstract

We consider a macroscopic quantum system with unitarily evolving pure state t∈ H and take it for granted that different macro states correspond to mutually orthogonal, high-dimensional subspaces H (macro spaces) of H. Let P denote the projection to H. We prove two facts about the evolution of the superposition weights \|P_t\|2: First, given any T>0, for most initial states 0 from any particular macro space Hμ (possibly far from thermal equilibrium), the curve t \|P t\|2 is approximately the same (i.e., nearly independent of 0) on the time interval [0,T]. And second, for most 0 from Hμ and most t∈[0,∞), \|P t\|2 is close to a value Mμ that is independent of both t and 0. The first is an instance of the phenomenon of dynamical typicality observed by Bartsch, Gemmer, and Reimann, and the second modifies, extends, and in a way simplifies the concept, introduced by von Neumann, now known as normal typicality.