Exponential bound on information spreading induced by quantum many-body dynamics with long-range interactions

TL;DR

This paper introduces a new exponential bound on quantum information spreading in long-range interacting many-body systems, improving understanding of entanglement growth and correlations beyond traditional Lieb-Robinson limits.

Contribution

The authors derive a novel exponential bound on the number of spins that can become correlated after evolution, applicable to a broad class of long-range Hamiltonians.

Findings

Bound applies to long-range interactions with exponential accuracy

Demonstrates properties not derivable from Lieb-Robinson bounds

Provides new insights into entanglement dynamics in quantum systems

Abstract

The dynamics of quantum systems strongly depends on the local structure of the Hamiltonian. For short-range interacting systems, the well-known Lieb-Robinson bound defines the effective light cone with an exponentially small error with respect to the spatial distance, whereas we can obtain only polynomially small error for distance in long-range interacting systems. In this paper, we derive a qualitatively new bound for quantum dynamics by considering how many spins can correlate with each other after time evolution. Our bound characterizes the number of spins which support the many-body entanglement with exponentially small error and is valid for large class of Hamiltonians including long-range interacting systems. To demonstrate the advantage of our approach in quantum many-body systems, we apply our bound to prove several fundamental properties which have not be derived from the Lieb-Robinson bound.