Litcius/Paper detail

Temporal Entanglement in Chaotic Quantum Circuits

Alessandro Foligno, Tianci Zhou, Bruno Bertini

2023Physical Review X43 citationsDOIOpen Access PDF

Abstract

The concept of space evolution (or space-time duality) has emerged as a promising approach for studying quantum dynamics. The basic idea involves exchanging the roles of space and time, evolving the system using a space transfer matrix rather than the time evolution operator. The infinite-volume limit is then described by the fixed points of the latter transfer matrix, also known as influence matrices. To establish the potential of this method as a bona fide computational scheme, it is important to understand whether the influence matrices can be efficiently encoded in a classical computer. Here we begin this quest by presenting a systematic characterization of their entanglement—dubbed temporal entanglement—in chaotic quantum systems. We consider the most general form of space evolution, i.e., evolution in a generic spacelike direction, and present two fundamental results. First, we show that temporal entanglement always follows a volume law in time. Second, we identify two marginal cases—(i) pure space evolution in generic chaotic systems and (ii) any spacelike evolution in dual-unitary circuits—where Rényi entropies with index larger than one are sublinear in time while the von Neumann entanglement entropy grows linearly. We attribute this behavior to the existence of a product state with large overlap with the influence matrices. This unexpected structure in the temporal entanglement spectrum might be the key to an efficient computational implementation of the space evolution.

Topics & Concepts

Quantum entanglementChaoticSublinear functionTime evolutionQuantumStatistical physicsMathematicsPhysicsComputer scienceQuantum mechanicsDiscrete mathematicsArtificial intelligenceQuantum many-body systemsNeural Networks and Reservoir ComputingQuantum Information and Cryptography