用先进声张力亚稳流体探测器对铀进行9Mv直线光中子探测

IF 0.5 Q4 NUCLEAR SCIENCE & TECHNOLOGY

Journal of Nuclear Engineering and Radiation Science Pub Date : 2023-07-11 DOI:10.1115/1.4062951

N. Boyle, S. Ozerov, C. Harabagiu, R. Taleyarkhan

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引用次数: 0

摘要

讨论了利用声张力亚稳态流体检测器(ATMFD)传感器技术对特殊核材料(SNM)进行的有源光子中子探测研究，为在极端15000 R h-1 (9 MeV端点)x射线光束下实现特殊核材料(SNM)的实时探测提供了证据。描述了使用两种经济型E-ATMFD设计的3.2 kg DU检测实验，即E-ATMFD。0和E-ATMFD.Ver。1，分别在0.1米至10米的距离内-包括直接在询问光束内的E-ATMFD。在相似的条件下，100%光子抑制(即0 cpm，带光束，无SNM)， E-ATMFD.Ver。与E-ATMFD.Ver.0相比，1设计能够在低驱动功率约10倍的情况下获得约6倍(600%)的增益(有光束和SNM)。使用E-ATMFD.Ver，灵敏度增益提高到~27倍(即2,700%)。工作功率为0.99 W，背景计数速率为~1 cpm。E-ATMFD.Ver。在~0.56 W的驱动功率下，直接置于15000 R/h的光束中，证明了100%的光子盲性(0 cpm);包括SNM目标导致计数率高达50 cpm -揭示了E-ATMFD.Ver。1作为潜在的现场能力，可以在几秒钟内从光裂变中子信号中探测到基于u的SNMs，即使直接部署在询问光子束中。

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9Mv Linac Photo-Neutron Interrogation Of Uranium With Advanced Acoustically Tensioned Metastable Fluid Detectors

Active special nuclear material (SNM) photoneutron interrogation research with Acoustically Tensioned Metastable Fluid Detector (ATMFD) sensor technology is discussed which provides evidence for enabling real time detection of special nuclear material (SNM) even when deployed under extreme 15,000 R h-1 (9 MeV endpoint) X-ray beams. Experiments to detect 3.2 kg DU are described with use of two designs of the economical E-ATMFD, viz., E-ATMFD.Ver.0 and E-ATMFD.Ver.1, respectively, at standoffs ranging from 0.1 m to 10 m - including with the E-ATMFD directly within the interrogating beam. Under similar conditions and with 100% photon rejection (i.e., 0 cpm with beam on, and w/o SNM), the E-ATMFD.Ver.1 design was shown capable of ~6x (600%) higher gain at ~10x lower drive powers over E-ATMFD.Ver.0 (with beam on and with SNM). The sensitivity gain rises to ~27x (i.e., 2,700%) with the E-ATMFD.Ver.1 operating at 0.99 W and a background count rate of ~1 cpm. The E-ATMFD.Ver.1 demonstrated 100% photon blindness (0 cpm) while operating at ~0.56 W drive power and placed directly within the beam under 15,000 R/h; including the SNM target led to a count rate of up to 50 cpm - revealing the E-ATMFD.Ver.1 as potentially field-capable for detecting U-based SNMs within seconds from photofission neutron signals, even when deployed directly within the interrogating photon beam.

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来源期刊

Journal of Nuclear Engineering and Radiation Science NUCLEAR SCIENCE & TECHNOLOGY-

CiteScore

1.30

自引率

0.00%

发文量

期刊介绍： The Journal of Nuclear Engineering and Radiation Science is ASME’s latest title within the energy sector. The publication is for specialists in the nuclear/power engineering areas of industry, academia, and government.