Optimal bounds on the speed of subspace evolution

TL;DR

This paper derives optimal bounds on the speed of quantum subspace evolution, generalizing the Mandelstam-Tamm inequality to subspaces and including unbounded Hamiltonians, advancing understanding of quantum dynamics.

Contribution

It introduces the concept of maximal angle between subspaces to establish the first optimal bounds on subspace evolution speed, extending previous single-state limits.

Findings

Derived bounds are optimal and generalize Mandelstam-Tamm inequality.

Includes cases with unbounded Hamiltonians.

Provides a framework for analyzing quantum subspace evolution speed.

Abstract

By a quantum speed limit one usually understands an estimate on how fast a quantum system can evolve between two distinguishable states. The most known quantum speed limit is given in the form of the celebrated Mandelstam-Tamm inequality that bounds the speed of the evolution of a state in terms of its energy dispersion. In contrast to the basic Mandelstam-Tamm inequality, we are concerned not with a single state but with a (possibly infinite-dimensional) subspace which is subject to the Schroedinger evolution. By using the concept of maximal angle between subspaces we derive optimal bounds on the speed of such a subspace evolution. These bounds may be viewed as further generalizations of the Mandelstam-Tamm inequality. Our study includes the case of unbounded Hamiltonians.