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http://dx.doi.org/10.1016/j.net.2021.03.021

Neutron diagnostics using nickel foil activation analysis in the KSTAR  

Chae, San (Korea Atomic Energy Research Institute)
Lee, Jae-Yong (Hanyang University)
Kim, Yong-Soo (Hanyang University)
Publication Information
Nuclear Engineering and Technology / v.53, no.9, 2021 , pp. 3012-3017 More about this Journal
Abstract
The spatial distribution and the energy spectrum of the neutron yield were investigated with the neutron activation analysis and MCNP simulation was carried out to verify the analysis results and to extend the results to a 3D mapping of the neutron yield distribution in the KSTAR. High purity Ni specimen was selected in the neutron activation analysis. Total neutron yields turned out to be 3.76 × 1012 n/s - 7.56 × 1012 n/s at the outer vessel of the KSTAR, two orders of magnitude lower than those at the inner vessel of the KSTAR, which demonstrates the attenuation of neutron yield while passing through the different structural materials of the reactor. Based on the fully expanded 3D simulation results, 2D cross-sectional distributions of the neutron yield on XY and ZX planes of KSTAR were examined. The results reveal that the neutron yield has its maximum concentration near the center of blanket and decreases with increasing proximity to the vacuum vessel wall.
Keywords
Neutron activation analysis; KSTAR; Neutron yield; Gamma spectroscopy; MCNP;
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1 A.F. Rowcliffe, C.E. Kessel, Y. Katoh, L.M. Garrison, L. Tan, Y. Yamamoto, F.W. Wiffen, Materials-engineering challenges for the fusion core and lifetime components of the fusion nuclear science facility, Nucl. Mater. Energy 16 (2018) 82-87.   DOI
2 O.N. Jarvis, E.W. Clipsham, M.A. Hone, B.J. Laundy, M. Pillon, M. Rapisarda, G.J. Sadler, P. van Belle, K.A. Verschuur, Use of activation technique for the measurement of neutron yields from deuterium plasmas at the joint European torus, Fusion Technol. 20 (1991) 265-284.   DOI
3 S. Jednorog, E. Laszynska, P. Batistoni, B. Bienkowska, A. Cufar, Z. Ghani, L. Giacomelli, A. Klix, S. Loreti, K. Mikszuta, L. Packer, A. Peacock, M. Pillon, S. Popovichev, M. Rebai, D. Rigamonti, N. Roberts, M. Tardocchi, D. Thomas, Activation measurements in support of the 14MeV neutron calibration of JET neutron monitors, Fusion Eng. Des. 125 (2017) 50-56.   DOI
4 C.S. Kim, S.P. Hong, M.S. Cheon, B.S. Kang, S. Cho, Neutron diagnostics using Compton suppression gamma-ray spectrometer for tritium breeding blanket experiments, Fusion Eng. Des. 109-111 (2016) 88-92.   DOI
5 MCNP - a General Monte Carlo N-Particle Trasnport Code, Version 5, 2000.
6 A.C. England, S.G. Lee, Y.S. Lee, Z.Y. Chen, J.W. Yoo, W.C. Kim, J.G. Kwak, M. Kwon, Neutron emission from KSTAR Ohmically heated plasmas, Phys. Lett., A 375 (2011) 3095-3099.   DOI
7 K. Ehrlich, Materials research towards a fusion reactor, Fusion Eng. Des. 56-57 (2001) 71-82.   DOI
8 A.V. Spitsyn, N.P. Bobyr, T.V. Kulevoy, P.A. Fedin, A.I. Semennikov, V.S. Stolbunov, Use of MeV energy ion accelerators to simulate the neutron damage in fusion reactor materials, Fusion Eng. Des. 146 (2019) 1313-1316.   DOI
9 K. Tian, P. Calderoni, B.-E. Ghidersa, A. Klix, Feasibility study of a neutron activation system for EU test blanket systems, Fusion Eng. Des. 109-111 (2016) 1517-1521.   DOI
10 F.H. Stefaan pomme, Piotr Robouch, Nestor Etxebarria, Gorka Arana, Neutron activation analysis with K0-standardisation: general formalism and procedure, in: SCK-CEN, SCK-CEN, 1997.
11 C.C. Negoita, Measurement of Neutron Flux Spectra in a Tungsten Benchmark by Neutron Foil Activation Method, Shaker, Germany, 2004.
12 J.-G. Kwak, Y.S. Lee, D.R. Lee, C.S. Kim, H.S. Kim, H.J. Lee, K. Shinohara, Accumulated 2-D neutron flux distribution during KSTAR operation, Fusion Eng. Des. 136 (2018) 777-781.   DOI
13 R.C. Koch, Chapter 2 - activation analysis.theoretical considerations, in: R.C. Koch (Ed.), Activation Analysis Handbook, Academic Press, 1960, pp. 5-10.
14 T. Vasilopoulou, I.E. Stamatelatos, P. Batistoni, N. Fonnesu, R. Villari, J. Naish, S. Popovichev, B. Obryk, Activation foil measurements at JET in preparation for D-T plasma operation, Fusion Eng. Des. 146 (2019) 250-255.   DOI
15 R.R. Greenberg, P. Bode, E.A. De Nadai Fernandes, Neutron activation analysis: a primary method of measurement, Spectrochim. Acta B Atom Spectrosc. 66 (2011) 193-241.   DOI
16 A.F. Rowcliffe, L.M. Garrison, Y. Yamamoto, L. Tan, Y. Katoh, Materials challenges for the fusion nuclear science facility, Fusion Eng. Des. 135 (2018) 290-301.   DOI
17 R.C. Koch, Chapter 3 - activation analysis.experimental methods, in: R.C. Koch (Ed.), Activation Analysis Handbook, Academic Press, 1960, pp. 11-15.
18 M.B. Chadwick, M. Herman, P. Oblozinsky, M.E. Dunn, Y. Danon, A.C. Kahler, D.L. Smith, B. Pritychenko, G. Arbanas, R. Arcilla, R. Brewer, D.A. Brown, R. Capote, A.D. Carlson, Y.S. Cho, H. Derrien, K. Guber, G.M. Hale, S. Hoblit, S. Holloway, T.D. Johnson, T. Kawano, B.C. Kiedrowski, H. Kim, S. Kunieda, N.M. Larson, L. Leal, J.P. Lestone, R.C. Little, E.A. McCutchan, R.E. MacFarlane, M. MacInnes, C.M. Mattoon, R.D. McKnight, S.F. Mughabghab, G.P.A. Nobre, G. Palmiotti, A. Palumbo, M.T. Pigni, V.G. Pronyaev, R.O. Sayer, A.A. Sonzogni, N.C. Summers, P. Talou, I.J. Thompson, A. Trkov, R.L. Vogt, S.C. van der Marck, A. Wallner, M.C. White, D. Wiarda, P.G. Young, ENDF/B-VII.1 nuclear data for science and technology: cross sections, covariances, fission product yields and decay data, Nucl. Data Sheets 112 (2011) 2887-2996.   DOI