Fabry–Pérot纳米结构中中子的俘获及其在冷中子寿命研究中的潜在应用

IF 1 Q3 NUCLEAR SCIENCE & TECHNOLOGY
M. Maaza, B. Pardo, D. Hamidi, M. Akbari, R. Morad, M. Henini, A. Gibaud
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引用次数: 0

摘要

与中子全反射现象相关的是所谓的受抑全反射,也称为中子通道,在热中子和冷中子中都可以观察到。在这一贡献中,这种现象在各种不同的Fabry–Pérot纳米共振配置中得到了验证;即:(i)双反射和透射中子Fabry–Pérot纳米谐振器(Ni/V/Ni/Si衬底),(ii)基于同位素的中子Fabry-Pérot纳米谐振器(58Ni/62Ni/58Ni/硅衬底),以及(iii)8个叠置(B4C/Ti/B4C)单纳米谐振器的多层中子Fabry-Pérot纳米谐振器。虽然这种Fabry–Pérot纳米谐振器允许有效的中子捕获,但这种纳米谐振器中自由中子捕获时间的精度受海森堡不确定性的控制,因此为潜在寿命研究提供了一种额外的有吸引力的精确方法。根据Fabry–Pérot纳米谐振器的配置和可用的冷中子束,发现捕获时间在3到19 ps的时间范围内。虽然这一贡献的主要目的是验证在各种配置中以皮秒精度在纳米结构法布里-佩罗谐振器中捕获冷中子的可能性,但希望这些初步结果将引起中子寿命群体和中子散射群体的兴趣。将这种捕获方法潜在地集成到瓶或束方法中,将阐明两种方法之间中子寿命差异的根源。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
On the trapping of neutrons in Fabry–Pérot nano-structures and potential applications for cold neutron lifetime Investigations
Correlated to the neutron total reflection phenomenon is the so-called frustrated total reflection, also known as neutron channeling, observed with both thermal and cold neutrons. Within this contribution, such a phenomenon is validated in various additional distinctive Fabry–Pérot nano-resonating configurations; namely in: (i) dual reflection and transmission neutron Fabry–Pérot nano-resonator (Ni/V/Ni/Si substrate), (ii) isotope-based neutron Fabry–Pérot nano-resonator (58Ni/62Ni/58Ni/Silicon substrate), and (iii) multilayered neutron Fabry–Pérot nano-resonator of 8 superposed (B4C/Ti/B4C) single nano-resonators. While such Fabry–Pérot nano-resonators allow effective neutron trapping, the precision of the trapping time of free neutrons in such nano-resonators is governed by the Heisenberg uncertainty and hence offers, a priori, an additional attractive precise approach for potential lifetime investigations. Depending on the configuration of the Fabry–Pérot nano-resonators and the available cold neutron beam, the trapping time is found to be within the temporal regime of 3 to 19 ps. While the main intention of this contribution is to validate the possibility of trapping cold neutrons in nano-structured Fabry–Pérot resonators with a picosecond precision in various configurations, it is hoped that these preliminary results will attract the interest of the neutron lifetime community specifically and the neutron scattering community in general. The potential integration of such trapping method into the bottle or beam methods would elucidate the origin of the difference in neutron lifetime between the two approaches.
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来源期刊
Journal of Neutron Research
Journal of Neutron Research NUCLEAR SCIENCE & TECHNOLOGY-
CiteScore
2.30
自引率
9.10%
发文量
23
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