Directly Measuring a Multiparticle Quantum Wave Function via Quantum Teleportation

Ming Cheng Chen; Yuan Li; Run Ze Liu; Dian Wu; Zu En Su; Xi Lin Wang; Li Li; Nai Le Liu; Chao Yang Lu; Jian Wei Pan

doi:10.1103/PhysRevLett.127.030402

Directly Measuring a Multiparticle Quantum Wave Function via Quantum Teleportation

Ming Cheng Chen
, Yuan Li
, Run Ze Liu
, Dian Wu
, Zu En Su
, Xi Lin Wang
, Li Li
, Nai Le Liu
, Chao Yang Lu
, Jian Wei Pan

University of Science and Technology of China

Research output: Contribution to journal › Article › peer-review

15 Scopus citations

Abstract

We propose a new method to directly measure a general multiparticle quantum wave function, a single matrix element in a multi-particle density matrix, by quantum teleportation. The density matrix element is embedded in a virtual logical qubit and is nondestructively teleported to a single physical qubit for readout. We experimentally implement this method to directly measure the wave function of a photonic mixed quantum state beyond a single photon using a single observable for the first time. Our method also provides an exponential advantage over the standard quantum state tomography in measurement complexity to fully characterize a sparse multiparticle quantum state.

Original language	English
Article number	030402
Journal	Physical Review Letters
Volume	127
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevLett.127.030402
State	Published - 16 Jul 2021
Externally published	Yes

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10.1103/PhysRevLett.127.030402

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title = "Directly Measuring a Multiparticle Quantum Wave Function via Quantum Teleportation",

abstract = "We propose a new method to directly measure a general multiparticle quantum wave function, a single matrix element in a multi-particle density matrix, by quantum teleportation. The density matrix element is embedded in a virtual logical qubit and is nondestructively teleported to a single physical qubit for readout. We experimentally implement this method to directly measure the wave function of a photonic mixed quantum state beyond a single photon using a single observable for the first time. Our method also provides an exponential advantage over the standard quantum state tomography in measurement complexity to fully characterize a sparse multiparticle quantum state.",

author = "Chen, \{Ming Cheng\} and Yuan Li and Liu, \{Run Ze\} and Dian Wu and Su, \{Zu En\} and Wang, \{Xi Lin\} and Li Li and Liu, \{Nai Le\} and Lu, \{Chao Yang\} and Pan, \{Jian Wei\}",

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AU - Chen, Ming Cheng

AU - Li, Yuan

AU - Liu, Run Ze

AU - Wu, Dian

AU - Su, Zu En

AU - Wang, Xi Lin

AU - Li, Li

AU - Liu, Nai Le

AU - Lu, Chao Yang

AU - Pan, Jian Wei

PY - 2021/7/16

Y1 - 2021/7/16

N2 - We propose a new method to directly measure a general multiparticle quantum wave function, a single matrix element in a multi-particle density matrix, by quantum teleportation. The density matrix element is embedded in a virtual logical qubit and is nondestructively teleported to a single physical qubit for readout. We experimentally implement this method to directly measure the wave function of a photonic mixed quantum state beyond a single photon using a single observable for the first time. Our method also provides an exponential advantage over the standard quantum state tomography in measurement complexity to fully characterize a sparse multiparticle quantum state.

AB - We propose a new method to directly measure a general multiparticle quantum wave function, a single matrix element in a multi-particle density matrix, by quantum teleportation. The density matrix element is embedded in a virtual logical qubit and is nondestructively teleported to a single physical qubit for readout. We experimentally implement this method to directly measure the wave function of a photonic mixed quantum state beyond a single photon using a single observable for the first time. Our method also provides an exponential advantage over the standard quantum state tomography in measurement complexity to fully characterize a sparse multiparticle quantum state.

UR - https://www.scopus.com/pages/publications/85110711538

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DO - 10.1103/PhysRevLett.127.030402

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VL - 127

JO - Physical Review Letters

JF - Physical Review Letters

IS - 3

M1 - 030402

ER -

Directly Measuring a Multiparticle Quantum Wave Function via Quantum Teleportation

Abstract

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