Cross-sections of residual nuclei from deuteron irradiation of thin thorium target at energy 7 GeV

Radek Vespalec,Anton Alexandrovich Baldin,Sergey Ivanovich Tyutyunikov,Jurabek Khushvaktov,Lukas Zavorka,Miroslav Zeman,Jitka Vrzalova,Jindrich Adam,Vsevolod Mikhailovich Tsoupko-Sitnikov,Alexander Alexandrovich Solnyshkin,A Plompen,P Schillebeeckx,S Oberstedt,S Kopecky,P Siegler,F.-J Hambsch,J Heyse,W Mondelaers

doi:10.1051/epjconf/201714609038

Radek Vespalec, Anton Alexandrovich Baldin + Show 16 more

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https://doi.org/10.1051/epjconf/201714609038

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Abstract

The residual nuclei yields are of great importance for the estimation of basic radiation-technology characteristics (like a total target activity, production of long-lived nuclides etc.) of accelerator driven systems planned for transmutation of spent nuclear fuel and for a design of radioisotopes production facilities. Experimental data are also essential for validation of nuclear codes describing various stages of a spallation reaction. Therefore, the main aim of this work is to add new experimental data in energy region of relativistic deuterons, as similar data are missing in nuclear databases. The sample made of thin natural thorium foil was irradiated at JINR Nuclotron accelerator with a deuteron beam of the total kinetic energy 7 GeV. Integral number of deuterons was determined with the use of aluminum activation detectors. Products of deuteron induced spallation reaction were qualified and quantified by means of gamma-ray spectroscopy method. Several important spectroscopic corrections were applied to obtain results of high accuracy. Experimental cumulative and independent cross-sections were determined for more than 80 isotopes including meta-stable isomers. The total uncertainty of results rarely exceeded 9%. Experimental results were compared with MCNP6.1 Monte-Carlo code predictions. Generally, experimental and calculated cross-sections are in a reasonably good agreement, with the exception of a few light isotopes in a fragmentation region, where the calculations are highly under-estimated. Measured data will be useful for future development of high-energy nuclear codes. After completion, final data will be added into the EXFOR database.

Highlights

The Nuclotron accelerator of Veksler and Baldin Laboratory of High-Energy Physics at Joint Institute for Nuclear Research is able to provide relativistic deuteron beams up to 8 GeV per nucleon and intensity up to 1010 particles per cycle [1]
The sample made of thin natural thorium foil was irradiated at JINR Nuclotron accelerator with a deuteron beam of the total kinetic energy 7 GeV
Several experiments were performed using various spallation targets in a frame of Energy and Transmutation of Radioactive Waste (E&T RAW) collaboration formed in the Joint Institute for Nuclear Research in Dubna in order to investigate possibilities of so called Relativistic Nuclear technologies (RNT) in the accelerator driven systems concept (ADS)

Summary

Introduction

The Nuclotron accelerator of Veksler and Baldin Laboratory of High-Energy Physics at Joint Institute for Nuclear Research is able to provide relativistic deuteron beams up to 8 GeV per nucleon and intensity up to 1010 particles per cycle [1]. Several experiments were performed using various spallation targets in a frame of Energy and Transmutation of Radioactive Waste (E&T RAW) collaboration formed in the Joint Institute for Nuclear Research in Dubna (http://et.jinr.ru) in order to investigate possibilities of so called Relativistic Nuclear technologies (RNT) in the accelerator driven systems concept (ADS). In the case of lower energies, the MCNP6 code uses so called data libraries (tables of evaluated nuclear data). In the case of accelerator driven systems, the range of needed nuclear data is extended up to several GeV. For higher particle energies above 150 MeV, the code uses nuclear models, sometimes referred as high-energy event generators

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