Holographic nanodiamond-polymer composite grating with unprecedented slow-neutron refractive index modulation amplitude

Elhoucine Hadden; Martin Fally; Yuko Iso; Tobias Jenke; Jürgen Klepp; Atsushi Kume; Koichi Umemoto; Yasuo Tomita

doi:10.1063/5.0186753

Holographic nanodiamond-polymer composite grating with unprecedented slow-neutron refractive index modulation amplitude

Elhoucine Hadden (Corresponding author), Martin Fally, Yuko Iso, Tobias Jenke, Jürgen Klepp, Atsushi Kume, Koichi Umemoto, Yasuo Tomita

Physics of Functional Materials

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

We demonstrate exceptionally high slow-neutron diffraction efficiency ( ≈ 70% of transmitted intensity diffracted to the first order) from a holographic nanodiamond-polymer composite grating of only tens of micrometers thickness at the average neutron wavelength of 5.3 nm. By meticulous choice of materials for extreme refractive index modulation in a thin grating structure, we overcome typical wavelength and angular selectivity issues usually encountered when pursuing high diffraction efficiencies with a thick grating. This achievement paves the way for the implementation of flux-efficient diffractive elements, well-suited for polychromatic beams, and weakly collimated slow-neutron beams.

Original language	English
Article number	071901
Number of pages	6
Journal	Applied Physics Letters
Volume	124
Issue number	7
DOIs	https://doi.org/10.1063/5.0186753
Publication status	Published - 12 Feb 2024

Austrian Fields of Science 2012

103021 Optics
103023 Polymer physics

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10.1063/5.0186753Licence: CC BY 4.0

https://phaidra.univie.ac.at/o:2067027Licence: CC BY 4.0

Cite this

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abstract = "We demonstrate exceptionally high slow-neutron diffraction efficiency ( ≈ 70% of transmitted intensity diffracted to the first order) from a holographic nanodiamond-polymer composite grating of only tens of micrometers thickness at the average neutron wavelength of 5.3 nm. By meticulous choice of materials for extreme refractive index modulation in a thin grating structure, we overcome typical wavelength and angular selectivity issues usually encountered when pursuing high diffraction efficiencies with a thick grating. This achievement paves the way for the implementation of flux-efficient diffractive elements, well-suited for polychromatic beams, and weakly collimated slow-neutron beams.",

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AU - Hadden, Elhoucine

AU - Fally, Martin

AU - Iso, Yuko

AU - Jenke, Tobias

AU - Klepp, Jürgen

AU - Kume, Atsushi

AU - Umemoto, Koichi

AU - Tomita, Yasuo

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AB - We demonstrate exceptionally high slow-neutron diffraction efficiency ( ≈ 70% of transmitted intensity diffracted to the first order) from a holographic nanodiamond-polymer composite grating of only tens of micrometers thickness at the average neutron wavelength of 5.3 nm. By meticulous choice of materials for extreme refractive index modulation in a thin grating structure, we overcome typical wavelength and angular selectivity issues usually encountered when pursuing high diffraction efficiencies with a thick grating. This achievement paves the way for the implementation of flux-efficient diffractive elements, well-suited for polychromatic beams, and weakly collimated slow-neutron beams.

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Holographic nanodiamond-polymer composite grating with unprecedented slow-neutron refractive index modulation amplitude

Abstract

Austrian Fields of Science 2012

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NeqstPi: Neutron Experiments on Quantum States at Pico Scale

Nanodiamond diffraction gratings for neutron optics

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Holographic nanodiamond-polymer composite grating with unprecedented slow-neutron refractive index modulation amplitude

Abstract

Austrian Fields of Science 2012

Access to Document

Other files and links

Fingerprint

Projects

NeqstPi: Neutron Experiments on Quantum States at Pico Scale

Nanodiamond diffraction gratings for neutron optics

Cite this