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Bibliographic Details
Main Authors: Huang, Yi-Te, Huang, Hsiang-Wei, Lin, Jhen-Dong, Miranowicz, Adam, Lambert, Neill, Chen, Guang-Yin, Nori, Franco, Chen, Yueh-Nan
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.16335
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author Huang, Yi-Te
Huang, Hsiang-Wei
Lin, Jhen-Dong
Miranowicz, Adam
Lambert, Neill
Chen, Guang-Yin
Nori, Franco
Chen, Yueh-Nan
author_facet Huang, Yi-Te
Huang, Hsiang-Wei
Lin, Jhen-Dong
Miranowicz, Adam
Lambert, Neill
Chen, Guang-Yin
Nori, Franco
Chen, Yueh-Nan
contents Quantum information scrambling (QIS) describes the rapid spread of initially localized information across an entire quantum many-body system through entanglement generation. Once scrambled, the original local information becomes encoded globally, inaccessible from any single subsystem. In this work, we introduce a circuit-based decoding protocol. By utilizing the concept of postselected closed timelike curves (PCTCs), we demonstrate how postselection allows us to interpret an ordinary quantum experiment as an example of a paradox-free trajectory, simulating a consistent time loop and reliable information recovery. Specifically, when conditioned on a final postselected outcome, this experiment can be interpreted as decoding the scrambled information even before the original information is generated. Furthermore, the success probability of the PCTC is governed by out-of-time-ordered correlations, which is a standard measure of QIS. We experimentally implement our protocol on cloud-based Quantinuum and IBM quantum processors. Our approach illuminates a unique quantum task under postselection: the causally consistent simulation of future-to-past scrambled information retrieval.
format Preprint
id arxiv_https___arxiv_org_abs_2501_16335
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Experimental simulation of postselected closed timelike curves for decoding scrambled quantum information
Huang, Yi-Te
Huang, Hsiang-Wei
Lin, Jhen-Dong
Miranowicz, Adam
Lambert, Neill
Chen, Guang-Yin
Nori, Franco
Chen, Yueh-Nan
Quantum Physics
Quantum information scrambling (QIS) describes the rapid spread of initially localized information across an entire quantum many-body system through entanglement generation. Once scrambled, the original local information becomes encoded globally, inaccessible from any single subsystem. In this work, we introduce a circuit-based decoding protocol. By utilizing the concept of postselected closed timelike curves (PCTCs), we demonstrate how postselection allows us to interpret an ordinary quantum experiment as an example of a paradox-free trajectory, simulating a consistent time loop and reliable information recovery. Specifically, when conditioned on a final postselected outcome, this experiment can be interpreted as decoding the scrambled information even before the original information is generated. Furthermore, the success probability of the PCTC is governed by out-of-time-ordered correlations, which is a standard measure of QIS. We experimentally implement our protocol on cloud-based Quantinuum and IBM quantum processors. Our approach illuminates a unique quantum task under postselection: the causally consistent simulation of future-to-past scrambled information retrieval.
title Experimental simulation of postselected closed timelike curves for decoding scrambled quantum information
topic Quantum Physics
url https://arxiv.org/abs/2501.16335