High-Transmission Neutron Optical Devices Utilizing Micro-Machined Structures

Connor Kapahi; Dusan Sarenac; Markus Bleuel; David G. Cory; Benjamin Heacock; Melissa E. Henderson; Michael G. Huber; Ivar Taminiau; Dmitry Pushin

doi:10.3390/qubs7010010

High-Transmission Neutron Optical Devices Utilizing Micro-Machined Structures

Connor Kapahi
, Dusan Sarenac
, Markus Bleuel
, David G. Cory
, Benjamin Heacock
, Melissa E. Henderson
, Michael G. Huber
, Ivar Taminiau
, Dmitry Pushin

Physics

University at Buffalo

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

1 Scopus citations

Abstract

Neutrons are a powerful probe in material science with unique penetrating abilities. A major challenge stems from the fact that neutron optical devices are limited to refractive indices on the order of (Formula presented.). By exploiting advances in precision manufacturing, we designed and constructed micro-meter period triangular grating with a high-aspect ratio of (Formula presented.). The manufacturing quality is demonstrated with white-light interferometric data and microscope imaging. Neutron-scattering experiment results are presented, showing agreement with refraction modelling. The capabilities of neutron Fresnel prisms and lenses based on this design are contrasted with existing neutron focusing techniques, and the path separation of a prism-based neutron interferometer is estimated.

Original language	English
Article number	10
Journal	Quantum Beam Science
Volume	7
Issue number	1
DOIs	https://doi.org/10.3390/qubs7010010
State	Published - Mar 2023

Keywords

neutron optics
neutron scattering

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10.3390/qubs7010010

Cite this

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title = "High-Transmission Neutron Optical Devices Utilizing Micro-Machined Structures",

abstract = "Neutrons are a powerful probe in material science with unique penetrating abilities. A major challenge stems from the fact that neutron optical devices are limited to refractive indices on the order of (Formula presented.). By exploiting advances in precision manufacturing, we designed and constructed micro-meter period triangular grating with a high-aspect ratio of (Formula presented.). The manufacturing quality is demonstrated with white-light interferometric data and microscope imaging. Neutron-scattering experiment results are presented, showing agreement with refraction modelling. The capabilities of neutron Fresnel prisms and lenses based on this design are contrasted with existing neutron focusing techniques, and the path separation of a prism-based neutron interferometer is estimated.",

keywords = "neutron optics, neutron scattering",

author = "Connor Kapahi and Dusan Sarenac and Markus Bleuel and Cory, \{David G.\} and Benjamin Heacock and Henderson, \{Melissa E.\} and Huber, \{Michael G.\} and Ivar Taminiau and Dmitry Pushin",

note = "Publisher Copyright: {\textcopyright} 2023 by the authors.",

year = "2023",

month = mar,

doi = "10.3390/qubs7010010",

language = "English",

volume = "7",

journal = "Quantum Beam Science",

issn = "2412-382X",

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TY - JOUR

T1 - High-Transmission Neutron Optical Devices Utilizing Micro-Machined Structures

AU - Kapahi, Connor

AU - Sarenac, Dusan

AU - Bleuel, Markus

AU - Cory, David G.

AU - Heacock, Benjamin

AU - Henderson, Melissa E.

AU - Huber, Michael G.

AU - Taminiau, Ivar

AU - Pushin, Dmitry

PY - 2023/3

Y1 - 2023/3

N2 - Neutrons are a powerful probe in material science with unique penetrating abilities. A major challenge stems from the fact that neutron optical devices are limited to refractive indices on the order of (Formula presented.). By exploiting advances in precision manufacturing, we designed and constructed micro-meter period triangular grating with a high-aspect ratio of (Formula presented.). The manufacturing quality is demonstrated with white-light interferometric data and microscope imaging. Neutron-scattering experiment results are presented, showing agreement with refraction modelling. The capabilities of neutron Fresnel prisms and lenses based on this design are contrasted with existing neutron focusing techniques, and the path separation of a prism-based neutron interferometer is estimated.

AB - Neutrons are a powerful probe in material science with unique penetrating abilities. A major challenge stems from the fact that neutron optical devices are limited to refractive indices on the order of (Formula presented.). By exploiting advances in precision manufacturing, we designed and constructed micro-meter period triangular grating with a high-aspect ratio of (Formula presented.). The manufacturing quality is demonstrated with white-light interferometric data and microscope imaging. Neutron-scattering experiment results are presented, showing agreement with refraction modelling. The capabilities of neutron Fresnel prisms and lenses based on this design are contrasted with existing neutron focusing techniques, and the path separation of a prism-based neutron interferometer is estimated.

KW - neutron optics

KW - neutron scattering

UR - https://www.scopus.com/pages/publications/85151089313

U2 - 10.3390/qubs7010010

DO - 10.3390/qubs7010010

M3 - Article

SN - 2412-382X

VL - 7

JO - Quantum Beam Science

JF - Quantum Beam Science

IS - 1

M1 - 10

ER -

High-Transmission Neutron Optical Devices Utilizing Micro-Machined Structures

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Keywords

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