Spin-energy entanglement of a time-focused neutron

J. C. Leiner; S. J. Kuhn; S. McKay; J. K. Jochum; F. Li; A. A.M. Irfan; F. Funama; D. Mettus; L. Beddrich; C. Franz; J. Shen; S. R. Parnell; R. M. Dalgliesh; M. Loyd; N. Geerits; G. Ortiz; C. Pfleiderer; R. Pynn

doi:10.1103/PhysRevApplied.22.L031005

Spin-energy entanglement of a time-focused neutron

J. C. Leiner
, S. J. Kuhn
, S. McKay
, J. K. Jochum
, F. Li
, A. A.M. Irfan
, F. Funama
, D. Mettus
, L. Beddrich
, C. Franz
, J. Shen
, S. R. Parnell
, R. M. Dalgliesh
, M. Loyd
, N. Geerits
, G. Ortiz
, C. Pfleiderer
, R. Pynn

Oak Ridge National Laboratory
Technical University of Munich
Indiana University Bloomington
University of Waterloo
Forschungszentrum Jülich (FZJ)
Paul Scherrer Institute
Delft University of Technology
Rutherford Appleton Laboratory
Technical University of Vienna
Institute for Advanced Study
Munich Center for Quantum Science and Technology (MCQST)

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

2 Scopus citations

Abstract

Intraparticle entanglement of individual particles such as neutrons could enable another class of scattering probes that are sensitive to entanglement in quantum systems and materials. In this work, we present experimental results demonstrating quantum contextuality as a result of entanglement between the spin and energy modes (i.e., degrees of freedom) of single neutrons in a beam using a pair of resonant radio-frequency neutron spin flippers in the modulated intensity with zero effort configuration. We verified the mode entanglement by measuring a Clauser-Horne-Shimony-Holt contextuality witness S defined in the spin and energy subsystems, observing a clear breach of the classical bound of |S|≤2, obtaining S=2.40±0.02. These entangled beams could enable alternative approaches for directly probing dynamics and entanglement in quantum materials whose low-energy excitation scales match those of the incident entangled neutron.

Original language	English
Article number	L031005
Journal	Physical Review Applied
Volume	22
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevApplied.22.L031005
State	Published - Sep 2024

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Leiner, J. C., Kuhn, S. J., McKay, S., Jochum, J. K., Li, F., Irfan, A. A. M., Funama, F., Mettus, D., Beddrich, L., Franz, C., Shen, J., Parnell, S. R., Dalgliesh, R. M., Loyd, M., Geerits, N., Ortiz, G., Pfleiderer, C., & Pynn, R. (2024). Spin-energy entanglement of a time-focused neutron. Physical Review Applied, 22(3), Article L031005. https://doi.org/10.1103/PhysRevApplied.22.L031005

@article{9fd8b17d40694884b5830d889ae18608,

title = "Spin-energy entanglement of a time-focused neutron",

abstract = "Intraparticle entanglement of individual particles such as neutrons could enable another class of scattering probes that are sensitive to entanglement in quantum systems and materials. In this work, we present experimental results demonstrating quantum contextuality as a result of entanglement between the spin and energy modes (i.e., degrees of freedom) of single neutrons in a beam using a pair of resonant radio-frequency neutron spin flippers in the modulated intensity with zero effort configuration. We verified the mode entanglement by measuring a Clauser-Horne-Shimony-Holt contextuality witness S defined in the spin and energy subsystems, observing a clear breach of the classical bound of |S|≤2, obtaining S=2.40±0.02. These entangled beams could enable alternative approaches for directly probing dynamics and entanglement in quantum materials whose low-energy excitation scales match those of the incident entangled neutron.",

author = "Leiner, \{J. C.\} and Kuhn, \{S. J.\} and S. McKay and Jochum, \{J. K.\} and F. Li and Irfan, \{A. A.M.\} and F. Funama and D. Mettus and L. Beddrich and C. Franz and J. Shen and Parnell, \{S. R.\} and Dalgliesh, \{R. M.\} and M. Loyd and N. Geerits and G. Ortiz and C. Pfleiderer and R. Pynn",

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doi = "10.1103/PhysRevApplied.22.L031005",

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T1 - Spin-energy entanglement of a time-focused neutron

AU - Leiner, J. C.

AU - Kuhn, S. J.

AU - McKay, S.

AU - Jochum, J. K.

AU - Li, F.

AU - Irfan, A. A.M.

AU - Funama, F.

AU - Mettus, D.

AU - Beddrich, L.

AU - Franz, C.

AU - Shen, J.

AU - Parnell, S. R.

AU - Dalgliesh, R. M.

AU - Loyd, M.

AU - Geerits, N.

AU - Ortiz, G.

AU - Pfleiderer, C.

AU - Pynn, R.

PY - 2024/9

Y1 - 2024/9

N2 - Intraparticle entanglement of individual particles such as neutrons could enable another class of scattering probes that are sensitive to entanglement in quantum systems and materials. In this work, we present experimental results demonstrating quantum contextuality as a result of entanglement between the spin and energy modes (i.e., degrees of freedom) of single neutrons in a beam using a pair of resonant radio-frequency neutron spin flippers in the modulated intensity with zero effort configuration. We verified the mode entanglement by measuring a Clauser-Horne-Shimony-Holt contextuality witness S defined in the spin and energy subsystems, observing a clear breach of the classical bound of |S|≤2, obtaining S=2.40±0.02. These entangled beams could enable alternative approaches for directly probing dynamics and entanglement in quantum materials whose low-energy excitation scales match those of the incident entangled neutron.

AB - Intraparticle entanglement of individual particles such as neutrons could enable another class of scattering probes that are sensitive to entanglement in quantum systems and materials. In this work, we present experimental results demonstrating quantum contextuality as a result of entanglement between the spin and energy modes (i.e., degrees of freedom) of single neutrons in a beam using a pair of resonant radio-frequency neutron spin flippers in the modulated intensity with zero effort configuration. We verified the mode entanglement by measuring a Clauser-Horne-Shimony-Holt contextuality witness S defined in the spin and energy subsystems, observing a clear breach of the classical bound of |S|≤2, obtaining S=2.40±0.02. These entangled beams could enable alternative approaches for directly probing dynamics and entanglement in quantum materials whose low-energy excitation scales match those of the incident entangled neutron.

UR - https://www.scopus.com/pages/publications/85205141267

U2 - 10.1103/PhysRevApplied.22.L031005

DO - 10.1103/PhysRevApplied.22.L031005

M3 - Article

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SN - 2331-7019

VL - 22

JO - Physical Review Applied

JF - Physical Review Applied

IS - 3

M1 - L031005

ER -

Spin-energy entanglement of a time-focused neutron

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