SINBAD ABSTRACT NEA-1553/52
Silicon Sphere (OKTAVIAN)
1. Name of Experiment:
------------------
Leakage Neutron and Gamma Spectra from 40 and 60 cm diameter Silicon
Sphere Pile With 14 MeV Neutrons (March 1987)
2. Purpose and Phenomena Tested:
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The leakage current spectrum from the outer surface of the sphere pile
with 14 MeV neutrons normalized per source neutron was measured [1], [2],
[3], [4]. The gamma-rays were produced from (n,xg) reactions.
3. Description of Source and Experimental Configuration:
----------------------------------------------------
The pulsed beam line of the intense 14 MeV neutron source facility
OKTAVIAN [5] at Osaka University was used. Neutrons were produced
by bombarding a 370 GBq tritium target with 250 keV deuteron beam.
The energy spectrum of the neutron source was measured using the same
detection system as for the leakage spectrum measurement. The spatial
distribution of the emitted neutrons was measured for the target
assembly, but for the purpose of the analysis an isotropic neutron
source distribution is assumed. The neutron source spectrum is
given in Table 1. The other information about the neutrons emission
is given elsewhere [6].
The neutron spectra were measured with the time-of-flight (TOF)
technique. A tritium neutron producing target was placed at the
center of the pile. A cylindrical liquid organic scintillator NE-218
was used as a neutron detector, which was located about 11 m from the
tritium target and at 55 deg. with respect to the deuteron beam axis.
A pre-collimator made of polyethylene-iron multi-layers was set between
the pile and the detector in order to reduce the background neutrons.
The aperture size of this collimator was determined so that the whole
surface of the pile facing the detector could be viewed. The details of
the experimental set-up are shown in Figure 1.
Gamma-rays were detected with a cylindrical NaI crystal and the
energy spectra were obtained from the unfolding process of the
gamma-ray pulse-height spectra, using a response matrix of the
NaI detector. The detector was located at 5.8 m distance from the
neutron source and counted the gamma-rays emitted from the sphere.
The energy spectrum of gamma-rays at the source is shown in Table 2,
and Figures 4 and 5. Time spectra of neutrons and gamma-rays from the
sphere were measured simultaneously with the pulse-height spectra by
means of a TOF technique.
The pile was made by filling a spherical vessels with grannular silicon.
The stainless steel (JIS SUS-304) vessel with 61.0 cm outer diameter
was equipped with a 20 cm inner diameter void at its center and a
11 cm diameter reentrant hole for the target beam duct. The external
and the internal vessel thickness was 0.5 cm and 0.2 cm respectively.
The details of the pile geometry are given in Figure 2. The gamma-ray
leakage spectrum has been also measured for a 40.0 cm diameter pile
shown in Figure 3.
Granular silicon was at least 99.9% pure, with density of 1.29 g/cm3.
The assumed composition of stainless steel is 18.5 % Chromium,
70.4 % Iron and 11.1 % Nickel, with density of 7.86 g/cm3.
4. Measurement System:
------------------
A cylindrical liquid organic scintillator NE-218 (12.7 cm-diam,
5.1 cm-long) was used as a neutron detector. The detector efficiency
was determined by combining:
1) the Monte Carlo calculation,
2) the measured efficiency derived from the TOF measurement of Cf-252
spontaneous fission spectrum and the Watt's spectrum, and
3) the measured efficiency from the leakage spectrum from a graphite
sphere, 30 cm in diameter with the similar detection system.
To monitor the absolute neutron spectrum per source neutron, a
cylindrical niobium foil was set in front of the tritium target and
irradiated during the TOF experiment. From the gamma-ray intensity
of the induced activity, Nb-92m and the integrated counts of the
source neutron spectrum, the absolute neutron leakage spectrum can
be obtained. The formulation of this procedure is described in the
Oktavian Report [7].
To measure the gamma spectra, OKTAVIAN was run in the pulsed mode
with a repetition frequency of 500 kHz. The pulse width was 3 ns in
FWHM and the difference in flight times between the 14 MeV neutrons
and the prompt gamma-rays was about 90 ns from the sphere to the
detector. Since those were enough to separate the gamma-rays from
the neutron background in the TOF spectra, the desired gamma-rays
could be discriminated from a neutron background.
The gamma emission spectra were dominated by the gamma-rays from
(n,n') and (n,2n) reactions rather than the gamma-rays from
(n,xg) reaction. The data are therefore available to the assessment
in the nuclear data for energy distributions of gamma-rays from
non-elastic scattering by high energy neutrons.
5. Description of Results and Analysis:
-----------------------------------
The measured neutron leakage spectrum from a 60 cm diameter silicon
pile is given in Table 3 and in Figure 6. Numerical data for the
gamma-ray leakage spectra, measured from a 40 cm and a 60 cm diameter
silicon piles are given in Tables 4 and 5 and in Figures 7 and 8
respectively.
In ref. [9] the neutron leakage spectra measurements from a 40 cm Si
file are mentioned. Only plots are available in Figure 9, and the energy
integrated data are given at 4 energy groups in Table 6.
Error Assessment:
The experimental errors in the measured neutron spectra include only
statistical deviation (1 s). The relative error to measure the niobium
activation foils is less than 1 % (0.4 to 1 %), which is not included.
In the measured gamma spectra the following sources were included
in the errors:
(a) Uncertainty in monitoring absolute fluxes of the source neutrons,
(b) Errors of the response matrix,
(c) Statistical deviation (1 s).
Example of Experiment Analysis:
Three sets of inputs are provided:
- two older 1–dimensional (1D) MCNP-4B inputs for 60cm Si pile experiment,
one model (file mcnp60_n.inp) for neutron, and the second (mcnp60_n.inp)
for gamma transport calculations.
- two routine MCNPX(5) (semi) 2–D models in which the neutron source or
the gamma source is specified (AL2dns.i, AL2dgs.i).
- Detailed 3–dimensional MCNPX(5) model including the full experimental
information for both neutron and gamma spectra (AL3dn.i).
- Detailed 3–dimensional MCNPX(5) model including the full experimental
information and explicit D-T source for gamma spectra analysis (AL3dg.i).
The D-T source routine (patch_DT) is needed to run this input.
Results using the recommended more accurate 2-D and 3-D models are discussed
in [10].
Older benchmark calculations with the simple 1D MCNP model and ENDF/B-III
silicon data are described in ref. [8]. Measured and calculated spectra are
shown in Figures 6, 7 and 8.
Ref. [9] presents the benchmark calculation performed by the MCNP-4A code
with JENDL-3.2, JENDL-FF, FENDL-1 and FENDL-2 (ENDF-VI) libraries. Calculated
and measured spectra for the 40 cm diameter silicon pile are shown in
Figure 9, and for the 60 cm diameter silicon pile in Figures 10, 12 and 13.
The results by A. Trkov using the MCNP-4B code and the EFF-3/ENDF/B-VI
evaluations are given in Figure 11.
6. Quality assessment:
-----------------
The OKTAVIAN SILICON 60 CM experiment can be ranked as
a benchmark quality experiment for nuclear data validation purposes.
In order to make a complete use of this benchmark experiment,
supplementary experimental information is advisable on:
- the neutron realistic effects below 3 MeV
(in particular the background subtraction method should be detailed)
– the gamma source measurements
– the gamma detector response function
– the gamma detector calibration
The OKTAVIAN SILICON 40 CM experiment is ranked as
a benchmark experiment of INTERMEDIATE quality because
the neutron leakage flux measurements are only available in graphical form
and their reading is approximate.
Moreover,supplementary experimental information is advisable on:
– the gamma source measurements
– the gamma detector response function
For detailed evaluation see [10].
7. Author/Organizer:
----------------
Experiment and analysis:
Chihiro Ichihara, Katsuhei Kobayashi:
Research Reactor Institute, Kyoto University
Noda, Sennan-gun, Osaka 590-04, Japan
Shu A. Hayashi:
Institute for Atomic Energy, Rikkyo University
2-5-1 Nagasaka, Yokosukas Kanagawa 240-01, Japan
Itsuro Kimura:
Department of Nuclear engineering, Faculty of Engineering,
Kyoto University
Yoshida-honmachi, Sakyo-ku, Kyoto 606, Japan
Junji Yamamoto, Akito Takahashi, T. Kanaoka, I. Murata, K. Sumita:
Department of Nuclear Engineering, Faculty of Engineering,
Osaka University
2-1, Yamada-oka, Suita, Osaka 565, Japan
Compiler of data for Sinbad:
S. Kitsos
OECD/NEA, 12 bd des Iles, 92130 Issy les Moulineaux, France
Quality assessment:
A. Milocco, Institut Jožef Stefan, Jamova 39, Ljubljana, Slovenia
Reviewer of compiled data:
A. Trkov
IAEA/Nuclear Data Section
Wagramerstrasse 5, P.O.Box 100, A-1400 Vienna, Austria
I. Kodeli
OECD/NEA, 12 bd des Iles, 92130 Issy les Moulineaux, France
8. Availability:
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Unrestricted
9. References:
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[1] Ichihara C., et al.: Proc. Int. Conf. on Nucl. Data for Sci.
and Technol., Mito, Japan, pp.319-322 (1988).
[2] Ichihara C., et al.: Proc. Second Specialists' Meeting on Nucl.
Data for Fusion Reactors (1991), JAERI-M 91-062 (1991).
[3] Yamamoto J. et al.: "Gamma-Ray Emission Spectra from Spheres with
14 MeV Neutron Source", JAERI-M 89-026, 232 (1989).
[4] Yamamoto J. et al.: "Integral Experiment on Gamma-Ray Production
at OKTAVIAN", JAERI-M 91-062, 118 (1991).
[5] Sumita K., et al.: Proc. 12th SOFT, Vol. 1 (1982)
[6] Yamamoto J. et al.: "Numerical Tables and Graphs of Leakage Neutron
Spectra from Slabs of Typical Shielding Material with D-T Neutron
Source", OKTAVIAN-Report A-8305, Dept. of Nuclear Eng.,
Osaka University (1983).
[7] Takahashi A., et el.: OKTAVIAN Report, C-83-02 (1983).
[8] Sub Working Group of Fusion Reactor Physics Subcommittee:
Collection of Experimental Data for Fusion Neutronics Benchmark,
JAERI-M-94-014, Feb. 1994.
[9] Fujio Maekawa, Masayuki Wada, Chihiro Ichihara, Yo Makita,
Akito Takahashi, Yukio Oyama:
Compilation of Benchmark Results for Fusion Related Nuclear Data,
JAERI-Data/Code 98-024, Nov. 1998.
[10] A. Milocco, Quality Assessment of the OKTAVIAN Benchmark Experiments,
IJS-DP-10214, April 2009
[11] A. Milocco, A. Trkov, MCNPX/MCNP5 Routine for Simulating D–T Neutron
Source in Ti-T Targets, IJS-DP-9988, July 2008
[12] A. Milocco, A. Trkov, I. Kodeli: "The OKTAVIAN TOF Experiments in SINBAD:
Evaluation of the Experimental Uncertainties",
Annals of Nuclear Energy 37 (2010) pp. 443-449
10. Data and Format:
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DETAILED FILE DESCRIPTIONS
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Filename Size[bytes] Content
---------------- ----------- -------------
1 oksi-abs.htm 14.722 This information file
2 oksi-exp.htm 19.247 Description of experiment
3 Oktavian.pdf 2,934,763 Document describing quality assessment of OKTAVIAN experiments
4 SI42dn.i 4,472 Routine (~2D) MCNP5(X) input with neutron source (Si 40cm)
5 SI42dg.i 3,666 Routine (~2D) MCNP5(X) input with gamma source (Si 40cm)
6 SI43dn.i 5,939 Detailed 3D MCNP5(X) input for neutron spectrum calc. (Si 40cm)
7 SI43dg.i 6,276 Detailed 3D MCNP5(X) input with DT source -gamma calc. (Si 40cm)
8 SI62dn.i 4,452 Routine (~2D) MCNP5(X) input with neutron source (Si 40cm)
9 SI62dg.i 3,644 Routine (~2D) MCNP5(X) input with gamma source (Si 40cm)
10 SI63dn.i 5,935 Detailed 3D MCNP5(X) input for neutron spectrum calc. (Si 40cm)
11 SI63dg.i 6,277 Detailed 3D MCNP5(X) input with DT source -gamma calc. (Si 40cm)
12 DT_MCNP5.TXT 51,672 patch with the source subroutines for MCNP5
to calculate 14-MeV D-T source (new revised version)
13 source.F 29,688 source.F subroutine for MCNPX version 2.6f
to calculate 14-MeV D-T source (new revised version)
14 srcdx.F 12,709 srcdx.F subroutine for MCNPX version 2.6f
containing also subroutines for numerics
to calculate 14-MeV D-T source (new revised version)
15 D-T.pdf 493,108 Document describing D–T source routine for MCNPX/MCNP5
16 mcnp60_n.inp 7.715 1D Input for MCNP4B neutron calculations - Si 60cm (OBSOLETE)
17 mcnp60_g.inp 1.878 1D Input for MCNP4B gamma calculations - Si 60 cm (OBSOLETE)
18 oksi-f1.gif 13.827 Figure 1: Experimental arrangement of the OKTAVIAN Facility
19 oksi-f2.gif 9.887 Figure 2: 60 cm diameter vessel (Type-III)
20 oksi-f3.gif 7.345 Figure 3: 40 cm diameter vessel (Type-II)
21 oksi-f4.gif 10.398 Figure 4: Gamma-ray emission spectrum from the neutron source
22 oksi-f5.jpg 41.826 Figure 5: Gamma-ray source spectrum from 1D MCNP input and Table 2
23 oksi-f6.gif 12.094 Figure 6: Neutron spectra from Si 60 cm pile, ref. [8]
24 oksi-f7.gif 9.797 Figure 7: Gamma-ray spectra from Si 40 cm pile, ref. [8]
25 oksi-f8.gif 10.441 Figure 8: Gamma-ray spectra from Si 60 cm pile, ref. [8]
26 oksi-f9.gif 25.898 Figure 9: Neutron spectra from Si 40 cm pile - ENDF/B-VI, ref. [9]
27 oksi-f10.gif 13.918 Figure 10: Neutron spectra from Si 60 cm pile, ref. [9]
28 oksi-f11.jpg 66.385 Figure 11: Neutron spectra from Si 60 cm pile - EFF-3, ENDF/B-VI (by A. Trkov)
29 oksi-f12.gif 18.042 Figure 12: Gamma-ray spectra from a Si 60 cm pile, ref. [9]
30 oksi-f13.gif 17.599 Figure 13: Gamma-ray spectra from a Si 60 cm pile - ENDF/B-VI, ref. [9]
31 j94-014.pdf 34.067.821 Reference
32 j98-024.pdf 12.837.046 Reference
33 ane-10.pdf 585,384 Reference
34 si40-n-exp.txt 8.899 Low quality neutron leakage spectrum for the Si-40cm shell experiment
File oksi-exp.htm contains the following tables:
Table 1: Neutron source spectrum for silicon
Table 2: Gamma-ray energy spectrum at the source
Table 3: Measured neutron leakage spectrum from a Si sphere of 60 cm diameter
Table 4: Measured gamma-ray leakage spectrum from a Si sphere of 40 cm diameter
Table 5: Measured gamma-ray leakage spectrum from a Si sphere of 60 cm diameter
Table 6: Integrated neutron flux from Si spheres of 40 and 60 cm diameter
Figures are included in GIF and JPG formats.
SINBAD Benchmark Generation Date: 02/2002
SINBAD Benchmark Last Update: 02/2010
