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Main Authors: Sarenac, D., Lailey, O., Garrad, D. V., Vadnere, P. R., Shentevski, N., Clark, C. W., Cory, D. G., Cotter, J. P., Ekinci, H., Huber, M. G., Paster, J. W., Tzeng, Y., Venero, D. Alba, Pushin, D. A.
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2603.16655
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author Sarenac, D.
Lailey, O.
Garrad, D. V.
Vadnere, P. R.
Shentevski, N.
Clark, C. W.
Cory, D. G.
Cotter, J. P.
Ekinci, H.
Huber, M. G.
Paster, J. W.
Tzeng, Y.
Venero, D. Alba
Pushin, D. A.
author_facet Sarenac, D.
Lailey, O.
Garrad, D. V.
Vadnere, P. R.
Shentevski, N.
Clark, C. W.
Cory, D. G.
Cotter, J. P.
Ekinci, H.
Huber, M. G.
Paster, J. W.
Tzeng, Y.
Venero, D. Alba
Pushin, D. A.
contents A recent proposal suggested that neutron orbital angular momentum (OAM) states could be detected via spin-polarized absorption in polarized 3He, with predicted cross-section variations linked to the neutron's OAM. We experimentally tested this hypothesis using spin-polarized neutron beams with OAM =-2 to 2, generated by fork-dislocation phase-gratings, and transmitted through a polarized 3He cell. Within statistical precision, no OAM-dependent change in the absorption cross section was observed. This null result places stringent constraints on polarized 3He-based OAM detection schemes. The absence of an effect in the given regime is traced to the proposal's disregard of the spatial character of neutron OAM: unlike spin, OAM arises from the transverse phase structure of the wavefunction and couples only through spatial gradients and overlap. The transverse extent of neutron OAM modes expands rapidly, producing a doughnut-shaped intensity profile with negligible overlap with on-axis 3He nuclei, while off-axis capture samples only a locally uniform phase and reduces the interaction to the known spin dependence. These results clarify the limits of absorptive nuclear methods for probing neutron OAM and emphasize the necessity of spatially resolved interactions in any viable detection scheme.
format Preprint
id arxiv_https___arxiv_org_abs_2603_16655
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Experimental Limit on Neutron Orbital Angular Momentum Detection Using Polarized 3He
Sarenac, D.
Lailey, O.
Garrad, D. V.
Vadnere, P. R.
Shentevski, N.
Clark, C. W.
Cory, D. G.
Cotter, J. P.
Ekinci, H.
Huber, M. G.
Paster, J. W.
Tzeng, Y.
Venero, D. Alba
Pushin, D. A.
Applied Physics
A recent proposal suggested that neutron orbital angular momentum (OAM) states could be detected via spin-polarized absorption in polarized 3He, with predicted cross-section variations linked to the neutron's OAM. We experimentally tested this hypothesis using spin-polarized neutron beams with OAM =-2 to 2, generated by fork-dislocation phase-gratings, and transmitted through a polarized 3He cell. Within statistical precision, no OAM-dependent change in the absorption cross section was observed. This null result places stringent constraints on polarized 3He-based OAM detection schemes. The absence of an effect in the given regime is traced to the proposal's disregard of the spatial character of neutron OAM: unlike spin, OAM arises from the transverse phase structure of the wavefunction and couples only through spatial gradients and overlap. The transverse extent of neutron OAM modes expands rapidly, producing a doughnut-shaped intensity profile with negligible overlap with on-axis 3He nuclei, while off-axis capture samples only a locally uniform phase and reduces the interaction to the known spin dependence. These results clarify the limits of absorptive nuclear methods for probing neutron OAM and emphasize the necessity of spatially resolved interactions in any viable detection scheme.
title Experimental Limit on Neutron Orbital Angular Momentum Detection Using Polarized 3He
topic Applied Physics
url https://arxiv.org/abs/2603.16655