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| Main Authors: | , |
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| Format: | Preprint |
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2025
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| Online Access: | https://arxiv.org/abs/2503.10939 |
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| _version_ | 1866916652418859008 |
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| author | Liu, Yaohua Torres, Peter |
| author_facet | Liu, Yaohua Torres, Peter |
| contents | Pioneer, a next-generation single-crystal neutron diffractometer, is under development for Oak Ridge National Laboratory's Second Target Station (STS). Designed to address a wide range of scientific questions, Pioneer will deliver homogeneous neutron beams with customizable size and divergence, and provide a polarized beam option. This article introduces its incident beam optics, highlighting the optimization methodology and the simulated performance. Pioneer will utilize a modified elliptical-straight guide for neutron transport and deploy slit packages and insertable apertures to control beam size and divergence. The optimized guide geometry matches the optimal-and-full-sample-illumination condition, and the beam control system effectively filters out unwanted neutrons while preserving the desired ones. Additionally, we have found that polygon-approximated guides provide satisfactory transport efficiency and beam homogeneity, eliminating the need of truly curved guides. To enhance neutronics performance and reduce cost, the coatings of supermirror elements are individually optimized to the lowest half-integer $m$-values that are sufficient to deliver the desired neutrons. After evaluating polarizing V-cavities and $^3$He spin filters over the default polarized wavelength band of 1.2-5.5~Å, we selected a translatable multichannel polarizing V-cavity as the incident beam polarizer. Strategically placed at a location where the beam divergence is low and a large in-guide gap has negligible impact on transport efficiency, the optimized V-cavity achieves an average $P^2T$ of approximately 35\%. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2503_10939 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | Incident beam optics optimization for the single crystal neutron diffractometer Pioneer with a polarized beam option Liu, Yaohua Torres, Peter Instrumentation and Detectors Materials Science Pioneer, a next-generation single-crystal neutron diffractometer, is under development for Oak Ridge National Laboratory's Second Target Station (STS). Designed to address a wide range of scientific questions, Pioneer will deliver homogeneous neutron beams with customizable size and divergence, and provide a polarized beam option. This article introduces its incident beam optics, highlighting the optimization methodology and the simulated performance. Pioneer will utilize a modified elliptical-straight guide for neutron transport and deploy slit packages and insertable apertures to control beam size and divergence. The optimized guide geometry matches the optimal-and-full-sample-illumination condition, and the beam control system effectively filters out unwanted neutrons while preserving the desired ones. Additionally, we have found that polygon-approximated guides provide satisfactory transport efficiency and beam homogeneity, eliminating the need of truly curved guides. To enhance neutronics performance and reduce cost, the coatings of supermirror elements are individually optimized to the lowest half-integer $m$-values that are sufficient to deliver the desired neutrons. After evaluating polarizing V-cavities and $^3$He spin filters over the default polarized wavelength band of 1.2-5.5~Å, we selected a translatable multichannel polarizing V-cavity as the incident beam polarizer. Strategically placed at a location where the beam divergence is low and a large in-guide gap has negligible impact on transport efficiency, the optimized V-cavity achieves an average $P^2T$ of approximately 35\%. |
| title | Incident beam optics optimization for the single crystal neutron diffractometer Pioneer with a polarized beam option |
| topic | Instrumentation and Detectors Materials Science |
| url | https://arxiv.org/abs/2503.10939 |