Study of the 176Hf(n,2n)175Hf cross section at 18.9 MeV

HNPS Advances in Nuclear Physics Pub Date : 2022-10-17 DOI:10.12681/hnps.3710

E. Tsivouraki, S. Chasapoglou, Michalis Serris, M. Axiotis, Georgios Gkatis, S. Harissopulos, M. Kokkoris, A. Lagoyannis, Stavros Patas, R. Vlastou

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Abstract

Neutron nuclear reactions can provide significant information in the field of nuclear physics and applications. Hafnium (Hf) is one of the rare-earth isotopes with a relative large neutron total cross-section in the thermal neutron energy region and neutron induced reactions in reactor materials could lead to the production of long-lived isomeric states of Hf isotopes. Thus, the knowledge of neutron cross-sections on Hf isotopes is of great importance for basic research in Nuclear Physics as well as for applications concerning the interaction of neutrons with matter. In this study measurements of experimental cross section for the 176Hf(n,2n)175Hf and 180Hf(n,n΄γ)180mHf reactions were carried out, using the activation technique. The neutron beam energy at 18.9 MeV was produced via the 3H(d,n)4He reaction at the 5.5 MeV Tandem Van de Graaf accelerator laboratory of NCSR “Demokritos”. A thin metallic foil of natural Hf was used, while for the determination of the neutron flux at the target position a reference foil of Al was placed at the back of the Hf target. The irradiation was continuous for 28 hours leading to a total neutron fluence of 1010 n/cm2 and a BF3 detector was used for monitoring the neutron flux during the irradiation. After the end of irradiation, the activity of the Hf target and the Al foil were measured off-line by two HPGe detectors. Both detector efficiencies were obtained using a calibrated 152Eu source, placed in the same distance as the target and the reference foil. The 176Hf(n,2n)175Hf reaction has been corrected from the contribution of 177Hf(n,3n)175Hf and the 174Hf(n,γ)175Hf reactions and the 180Hf(n,n΄γ)180mHf reaction from the 179Hf(n,γ)180mHf. Theoretical calculations of the 174Hf(n,2n)175Hf, 176Hf(n,2n)175Hf and 180Hf(n,n΄γ)180mHf reaction cross-sections have also been performed using the nuclear statistical code “EMPIRE 3.2.3” and they have been compared with the data.

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18.9 MeV下176Hf(n,2n)175Hf截面的研究

中子核反应在核物理和应用领域提供了重要的信息。铪(Hf)是热中子能区中子总截面较大的稀土同位素之一，反应堆材料中的中子诱导反应可产生Hf同位素的长寿命同分异构体态。因此，了解Hf同位素的中子截面对核物理学的基础研究以及中子与物质相互作用的应用具有重要意义。本研究采用活化技术测量了176Hf(n,2n)175Hf和180Hf(n,n΄γ)180mHf反应的实验截面。在NCSR“Demokritos”5.5 MeV串联Van de Graaf加速器实验室，通过3H(d,n)4He反应产生了18.9 MeV的中子束能量。使用天然Hf的薄金属箔，而在Hf靶的背面放置Al的参考箔来测定靶位置的中子通量。辐照持续28小时，总中子通量为1010 n/cm2，辐照过程中使用BF3探测器监测中子通量。辐照结束后，用两台HPGe探测器离线测量Hf靶和Al箔的活度。两个探测器的效率都是使用校准的152Eu源获得的，该源与目标和参考箔放置在相同的距离。由177Hf(n,3n)175Hf和174Hf(n，γ)175Hf的贡献修正了176Hf(n,2n)175Hf反应，由179Hf(n，γ)180mHf修正了180Hf(n,n΄γ)180mHf反应。用核统计程序“EMPIRE 3.2.3”对174Hf(n,2n)175Hf、176Hf(n,2n)175Hf和180Hf(n,n΄γ)180mHf反应截面进行了理论计算，并与实验数据进行了比较。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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HNPS Advances in Nuclear Physics

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