Mode-Entangled Neutron Beams: A possible new tool for exploring Quantum Materials

Stephen Kuhn; Samuel McKay; David Verge Baxter; Collin Leslie Broholm; Eric B Dees; Fankang Li; Roger Pynn; Abu Ashik Md. Irfan; Gerardo Ortiz; Jiazhou Shen; William Michael Snow; Vincent Vangelista

Mode-Entangled Neutron Beams: A possible new tool for exploring Quantum Materials

ORAL

Abstract

An entangled neutron beam is an intriguing potential probe of the properties of quantum materials. We have generated bipartite (spin-path) and tripartite (spin-path-energy) mode-entangled neutrons at both pulsed and continuous neutron sources. The subsystems of individual neutrons are entangled as proven by the violation of a contextuality inequality (similar to the Bell inequality). The entanglement length (i.e. path separation) was varied between 85 nm and 1600 nm, much smaller than the separations available to traditional neutron interferometry. The entanglement is reproducible across different beamlines, different beam collimations, different neutron wavelengths and with different mode entangling devices, with the primary limitation arising from the finite polarization of the neutron beam. A recent theoretical investigation has shown that neutron scattering by entangled electron spins in a dimer show unique scattering signatures for particular parameter values, encouraging us to believe that entangled neutron scattering may be a promising novel technique to probe highly-correlated, frustrated magnetic systems.

^*This work is supported by grants from the U.S. Departments of Energy and Commerce and from Indiana University.

March 16, 2021, 5:24 PM – March 16, 2021, 5:36 PM

Presenters

Stephen Kuhn
- Center for Exploration of Energy & Matter, Indiana University
- Indiana Univ - Bloomington

Authors

Stephen Kuhn
- Center for Exploration of Energy & Matter, Indiana University
- Indiana Univ - Bloomington
Samuel McKay
- Indiana Univ - Bloomington
David Verge Baxter
- Indiana Univ - Bloomington
Collin Leslie Broholm
- Johns Hopkins University
- Department of Physics and Astronomy and Institute for Quantum Matter, The Johns Hopkins University
- Department of Physics and Astronomy and Institute for Quantum Matter, Johns Hopkins University, Baltimore, Maryland 21218, USA
- Institute for Quantum Matter and Department of Physics and Astronomy, Johns Hopkins University
- Physics, The Johns Hopkins University
Eric B Dees
- Indiana Univ - Bloomington
Fankang Li
- Oak Ridge National Laboratory
Roger Pynn
- Physics, Indiana University
- Indiana Univ - Bloomington
Abu Ashik Md. Irfan
- Indiana Univ - Bloomington
Gerardo Ortiz
- Indiana Univ - Bloomington
- Department of Physics, Indiana University Bloomington
Jiazhou Shen
- Indiana Univ - Bloomington
William Michael Snow
- Indiana Univ - Bloomington
Vincent Vangelista
- Indiana Univ - Bloomington