Determination of the Secondary Neutron Flux at the Massive Natural Uranium Spallation Target

M. Zeman; J. Adam; A. A. Baldin; W. I. Furman; S. A. Gustov; K. Katovsky; J. Khushvaktov; I. I. Mar'In; F. Novotny; A. A. Solnyshkin; P. Tichy; V. M. Tsoupko-Sitnikov; S. I. Tyutyunnikov; R. Vespalec; J. Vrzalova; V. Wagner; L. Zavorka

doi:10.1016/j.phpro.2017.09.021

Determination of the Secondary Neutron Flux at the Massive Natural Uranium Spallation Target

M. Zeman, J. Adam, A. A. Baldin, W. I. Furman, S. A. Gustov, K. Katovsky, J. Khushvaktov, I. I. Mar'In, F. Novotny, A. A. Solnyshkin, P. Tichy, V. M. Tsoupko-Sitnikov, S. I. Tyutyunnikov, R. Vespalec, J. Vrzalova, V. Wagner, L. Zavorka

Research output: Contribution to journal › Conference article › peer-review

Abstract

The flux of secondary neutrons generated in collisions of the 660 MeV proton beam with the massive natural uranium spallation target was investigated using a set of monoisotopic threshold activation detectors. Sandwiches made of thin high-purity Al, Co, Au, and Bi metal foils were installed in different positions across the whole spallation target. The gamma-ray activity of products of (n,xn) and other studied reactions was measured offline with germanium semiconductor detectors. Reaction yields of radionuclides with half-life exceeding 100 min and with effective neutron energy thresholds between 3.6 MeV and 186 MeV provided us with information about the spectrum of spallation neutrons in this energy region and beyond. The experimental neutron flux was determined using the measured reaction yields and cross-sections calculated with the TALYS 1.8 nuclear reaction program and INCL4-ABLA event generator of MCNP6. Neutron spectra in the region of activation sandwiches were also modeled with the radiation transport code MCNPX 2.7. Neutron flux based on excitation functions from TALYS provides a reasonable description of the neutron spectrum inside the spallation target and is in good agreement with Monte-Carlo predictions. The experimental flux that uses INCL4 cross-sections rather underestimates the modeled spectrum in the whole region of interest, but the agreement within few standard deviations was reached as well. The paper summarizes basic principles of the method for determining the spectrum of high-energy neutrons without employing the spectral adjustment routines and points out to the need for model improvements and precise cross-section measurements.

Original language	English
Pages (from-to)	69-78
Number of pages	10
Journal	Physics Procedia
Volume	90
DOIs	https://doi.org/10.1016/j.phpro.2017.09.021
State	Published - 2017
Externally published	Yes
Event	Conference on the Application of Accelerators in Research and Industry, CAARI 2016 - Fort Worth, United States Duration: Oct 30 2016 → Nov 4 2016

Funding

This work was performed on the behalf of Energy and Transmutation collaboration at the JINR. Our group also wants to express thanks to Phasotron accelerator staff for their technical support. This work was financially supported by Ministry of Youth and Education and Ministry of Finances of the Czech Republic. The project was also supported from the LO1210, FEKT-S-14-2520 projects at the BUT. The author is the Brno Ph.D. Talent Scholarship Holder - Funded by the Brno City Municipality.

Keywords

ADS
neutron flux
spallation target
threshold activation detectors

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10.1016/j.phpro.2017.09.021

Cite this

Zeman, M., Adam, J., Baldin, A. A., Furman, W. I., Gustov, S. A., Katovsky, K., Khushvaktov, J., Mar'In, I. I., Novotny, F., Solnyshkin, A. A., Tichy, P., Tsoupko-Sitnikov, V. M., Tyutyunnikov, S. I., Vespalec, R., Vrzalova, J., Wagner, V., & Zavorka, L. (2017). Determination of the Secondary Neutron Flux at the Massive Natural Uranium Spallation Target. Physics Procedia, 90, 69-78. https://doi.org/10.1016/j.phpro.2017.09.021

@article{9eae9bdd7c694841a26f74334970ef19,

title = "Determination of the Secondary Neutron Flux at the Massive Natural Uranium Spallation Target",

abstract = "The flux of secondary neutrons generated in collisions of the 660 MeV proton beam with the massive natural uranium spallation target was investigated using a set of monoisotopic threshold activation detectors. Sandwiches made of thin high-purity Al, Co, Au, and Bi metal foils were installed in different positions across the whole spallation target. The gamma-ray activity of products of (n,xn) and other studied reactions was measured offline with germanium semiconductor detectors. Reaction yields of radionuclides with half-life exceeding 100 min and with effective neutron energy thresholds between 3.6 MeV and 186 MeV provided us with information about the spectrum of spallation neutrons in this energy region and beyond. The experimental neutron flux was determined using the measured reaction yields and cross-sections calculated with the TALYS 1.8 nuclear reaction program and INCL4-ABLA event generator of MCNP6. Neutron spectra in the region of activation sandwiches were also modeled with the radiation transport code MCNPX 2.7. Neutron flux based on excitation functions from TALYS provides a reasonable description of the neutron spectrum inside the spallation target and is in good agreement with Monte-Carlo predictions. The experimental flux that uses INCL4 cross-sections rather underestimates the modeled spectrum in the whole region of interest, but the agreement within few standard deviations was reached as well. The paper summarizes basic principles of the method for determining the spectrum of high-energy neutrons without employing the spectral adjustment routines and points out to the need for model improvements and precise cross-section measurements.",

keywords = "ADS, neutron flux, spallation target, threshold activation detectors",

author = "M. Zeman and J. Adam and Baldin, {A. A.} and Furman, {W. I.} and Gustov, {S. A.} and K. Katovsky and J. Khushvaktov and Mar'In, {I. I.} and F. Novotny and Solnyshkin, {A. A.} and P. Tichy and Tsoupko-Sitnikov, {V. M.} and Tyutyunnikov, {S. I.} and R. Vespalec and J. Vrzalova and V. Wagner and L. Zavorka",

note = "Publisher Copyright: {\textcopyright} 2017 The Authors. Published by Elsevier B.V.; Conference on the Application of Accelerators in Research and Industry, CAARI 2016 ; Conference date: 30-10-2016 Through 04-11-2016",

year = "2017",

doi = "10.1016/j.phpro.2017.09.021",

language = "English",

volume = "90",

pages = "69--78",

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Zeman, M, Adam, J, Baldin, AA, Furman, WI, Gustov, SA, Katovsky, K, Khushvaktov, J, Mar'In, II, Novotny, F, Solnyshkin, AA, Tichy, P, Tsoupko-Sitnikov, VM, Tyutyunnikov, SI, Vespalec, R, Vrzalova, J, Wagner, V & Zavorka, L 2017, 'Determination of the Secondary Neutron Flux at the Massive Natural Uranium Spallation Target', Physics Procedia, vol. 90, pp. 69-78. https://doi.org/10.1016/j.phpro.2017.09.021

TY - JOUR

T1 - Determination of the Secondary Neutron Flux at the Massive Natural Uranium Spallation Target

AU - Zeman, M.

AU - Adam, J.

AU - Baldin, A. A.

AU - Furman, W. I.

AU - Gustov, S. A.

AU - Katovsky, K.

AU - Khushvaktov, J.

AU - Mar'In, I. I.

AU - Novotny, F.

AU - Solnyshkin, A. A.

AU - Tichy, P.

AU - Tsoupko-Sitnikov, V. M.

AU - Tyutyunnikov, S. I.

AU - Vespalec, R.

AU - Vrzalova, J.

AU - Wagner, V.

AU - Zavorka, L.

PY - 2017

Y1 - 2017

N2 - The flux of secondary neutrons generated in collisions of the 660 MeV proton beam with the massive natural uranium spallation target was investigated using a set of monoisotopic threshold activation detectors. Sandwiches made of thin high-purity Al, Co, Au, and Bi metal foils were installed in different positions across the whole spallation target. The gamma-ray activity of products of (n,xn) and other studied reactions was measured offline with germanium semiconductor detectors. Reaction yields of radionuclides with half-life exceeding 100 min and with effective neutron energy thresholds between 3.6 MeV and 186 MeV provided us with information about the spectrum of spallation neutrons in this energy region and beyond. The experimental neutron flux was determined using the measured reaction yields and cross-sections calculated with the TALYS 1.8 nuclear reaction program and INCL4-ABLA event generator of MCNP6. Neutron spectra in the region of activation sandwiches were also modeled with the radiation transport code MCNPX 2.7. Neutron flux based on excitation functions from TALYS provides a reasonable description of the neutron spectrum inside the spallation target and is in good agreement with Monte-Carlo predictions. The experimental flux that uses INCL4 cross-sections rather underestimates the modeled spectrum in the whole region of interest, but the agreement within few standard deviations was reached as well. The paper summarizes basic principles of the method for determining the spectrum of high-energy neutrons without employing the spectral adjustment routines and points out to the need for model improvements and precise cross-section measurements.

AB - The flux of secondary neutrons generated in collisions of the 660 MeV proton beam with the massive natural uranium spallation target was investigated using a set of monoisotopic threshold activation detectors. Sandwiches made of thin high-purity Al, Co, Au, and Bi metal foils were installed in different positions across the whole spallation target. The gamma-ray activity of products of (n,xn) and other studied reactions was measured offline with germanium semiconductor detectors. Reaction yields of radionuclides with half-life exceeding 100 min and with effective neutron energy thresholds between 3.6 MeV and 186 MeV provided us with information about the spectrum of spallation neutrons in this energy region and beyond. The experimental neutron flux was determined using the measured reaction yields and cross-sections calculated with the TALYS 1.8 nuclear reaction program and INCL4-ABLA event generator of MCNP6. Neutron spectra in the region of activation sandwiches were also modeled with the radiation transport code MCNPX 2.7. Neutron flux based on excitation functions from TALYS provides a reasonable description of the neutron spectrum inside the spallation target and is in good agreement with Monte-Carlo predictions. The experimental flux that uses INCL4 cross-sections rather underestimates the modeled spectrum in the whole region of interest, but the agreement within few standard deviations was reached as well. The paper summarizes basic principles of the method for determining the spectrum of high-energy neutrons without employing the spectral adjustment routines and points out to the need for model improvements and precise cross-section measurements.

KW - ADS

KW - neutron flux

KW - spallation target

KW - threshold activation detectors

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U2 - 10.1016/j.phpro.2017.09.021

DO - 10.1016/j.phpro.2017.09.021

M3 - Conference article

AN - SCOPUS:85037700467

SN - 1875-3884

VL - 90

SP - 69

EP - 78

JO - Physics Procedia

JF - Physics Procedia

T2 - Conference on the Application of Accelerators in Research and Industry, CAARI 2016

Y2 - 30 October 2016 through 4 November 2016

ER -

Determination of the Secondary Neutron Flux at the Massive Natural Uranium Spallation Target

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