# The quasiprobability behind the out-of-time-ordered correlator

**Authors:** Nicole Yunger Halpern, Brian Swingle, Justin Dressel

arXiv: 1704.01971 · 2018-04-12

## TL;DR

This paper explores the quasiprobability underlying the out-of-time-ordered correlator (OTOC), revealing its structure, properties, and potential for distinguishing chaotic from integrable quantum systems, with implications for quantum information scrambling.

## Contribution

It introduces a generalized quasiprobability framework for the OTOC, analyzes measurement protocols, and demonstrates its effectiveness in characterizing quantum chaos and information scrambling.

## Key findings

- Quasiprobability distinguishes chaotic from integrable regimes.
- Negative and nonreal components indicate nonclassical behavior.
- Efficient measurement protocols reduce trial complexity exponentially.

## Abstract

Two topics, evolving rapidly in separate fields, were combined recently: The out-of-time-ordered correlator (OTOC) signals quantum-information scrambling in many-body systems. The Kirkwood-Dirac (KD) quasiprobability represents operators in quantum optics. The OTOC has been shown to equal a moment of a summed quasiprobability. That quasiprobability, we argue, is an extension of the KD distribution. We explore the quasiprobability's structure from experimental, numerical, and theoretical perspectives. First, we simplify and analyze the weak-measurement and interference protocols for measuring the OTOC and its quasiprobability. We decrease, exponentially in system size, the number of trials required to infer the OTOC from weak measurements. We also construct a circuit for implementing the weak-measurement scheme. Next, we calculate the quasiprobability (after coarse-graining) numerically and analytically: We simulate a transverse-field Ising model first. Then, we calculate the quasiprobability averaged over random circuits, which model chaotic dynamics. The quasiprobability, we find, distinguishes chaotic from integrable regimes. We observe nonclassical behaviors: The quasiprobability typically has negative components. It becomes nonreal in some regimes. The onset of scrambling breaks a symmetry that bifurcates the quasiprobability, as in classical-chaos pitchforks. Finally, we present mathematical properties. The quasiprobability obeys a Bayes-type theorem, for example, that exponentially decreases the memory required to calculate weak values, in certain cases. A time-ordered correlator analogous to the OTOC, insensitive to quantum-information scrambling, depends on a quasiprobability closer to a classical probability. This work not only illuminates the OTOC's underpinnings, but also generalizes quasiprobability theory and motivates immediate-future weak-measurement challenges.

## Full text

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## Figures

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## References

139 references — full list in the complete paper: https://tomesphere.com/paper/1704.01971/full.md

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