68-ER-166 TIT EVAL-SEP00 A.K.M.HARUN-AR-RASHID+
DIST-MAR02 20020205
----JENDL-3.3 MATERIAL 6837
-----INCIDENT NEUTRON DATA
------ENDF-6 FORMAT
HISTORY
2000-09 Evaluation was performed by A.K.M.Harun-ar-Rashid (tit),
M.Igashira (tit), T.Ohsaki (tit), and K.Shibata (jaeri).
2001-01 Compiled by K.Shibata (jaeri).
mf=1 General information
mt=451 Descriptive data and dictionary
mf=2 Resonance parameters
mt=151 Resolved resonances
Resonance range (1.0e-05 to 3000.0 eV).
Resolved resonance parameters from Ref.1 or 2 (Ehi=3000.0 eV)
The bound level at -40.4 eV has Gamma-n = 0.3953 eV and
Gamma-gamma = 0.092 eV. This choice gives the desired
value for the thermal capture cross section, 16.2 b.
Values of Gamma-gamma not given in Ref.1 or 2 are set to
0.092 eV.
The value for the scattering radius is 0.8295, taken from
Ref.3 with small change within the given error, so as to
reproduce the close value of the thermal neutron scattering
cross section recommended by mughabghab [3].
The highest energy resonance included is 2931.8 eV
No background cross section is given.
Calculated 2200-m/s cross sections and res. integrals
2200-m/s res. integ.
elastic 12.448 b -
capture 16.765 b 112.16 b
total 29.213 b -
mf=3 Neutron cross sections
mt= 1 Total cross section
Spherical optical model calculation was made by using
casthy code [ref.4]. Parameters are as follows,
V = 48.2-0.25*E-16.0*(N-Z)/A , r0=1.18, a0=0.63
Ws = 7.84+0.51*E , rs=1.29, as=0.63
Vso= 6.0 , rso=1.26, aso=0.63
(energies in MeV, lengths in fm).
mt= 2 Elastic scattering cross section
The cross sections were obtained by subtracting a sum of
reaction cross sections from the total cross sections.
mt= 4,51,52,.,.,74,91 Inelastic scattering cross sections
Calculated by using egnash code [5,6].
The direct-process component was considered for mt=51
from dwba calculation by dwucky code. [5,7]
The level scheme is given as follows:
no energy spin parity
g.s 0.00000 0.0 +
1 0.08060 2.0 +
2 0.26500 4.0 +
3 0.54550 6.0 +
4 0.78590 2.0 +
5 0.85940 3.0 +
6 0.91120 8.0 +
7 0.95620 4.0 +
8 1.07530 5.0 +
9 1.21600 6.0 +
10 1.34960 10.0 +
11 1.37600 7.0 +
12 1.45820 2.0 -
13 1.45990 0.0 +
14 1.51340 3.0 -
15 1.52840 2.0 +
16 1.55570 8.0 +
17 1.57220 4.0 -
18 1.59620 4.0 -
19 1.66240 1.0 -
20 1.66580 5.0 -
21 1.67880 4.0 +
22 1.69230 5.0 -
23 1.70310 2.0 +
24 1.78700 6.0 -
Levels above 1.8 MeV are assumed to be overlapping
mt= 16,17,22,28,32,103,104,105,107
(n,2n), (n,3n), (n,n'a), (n,n'p), (n,n'd)
(n,p), (n,d), (n,t), (n,a)
Calculated using egnash [5,6].
mt=102 Capture cross secton
The capture cross section is based on the statistical model
calculations. The measured data of Ref.8 were taken into
account. The direct and semidirect capture cross sections
were added above 2 MeV by using the quick gnash code [6,9].
mf=4 Angular distributions of secondary neutrons
mt=2
Calculated with the casthy code.
mt=16,17,22,28,32,
Assumed to be isotropic in the laboratory system.
mt=51,---,74,91
Calculated with the casthy code.
For mt=51, the dwba component was taken into account.
mf=5 Energy distributions of secondary neutrons
mt=16,17,22,28,32,91
Calculated with the egnash code.
mf=12 Photon production multiplicities
mt=16,17,22,28,51-74,91,102,103,104,107
Calculated with the egnash code.
mf=14 Photon angular distributions
mt=16,17,22,28,51-74,91,102,103,104,107
Assumed to be isotropic.
mf=15 Photon energy distributions
mt=16,17,22,28,91,102,103,104,107
Calculated with the egnash code.
For mt=102, the measured data [10] were included at 45 and
550 keV.
References
1. Landolt-Boernstein New Series I/16B (Aug 1998).
2. Y. Danon et al.: Nucl. Sci. Eng., 28, 61 (1998).
3. S. F. Mughabghab: "Neutron Cross Sections: Vol. 1,
Neutron Resonance Parameters and Thermal Cross Sections,
Part B: z=61-100," Academic Press (1984).
4. S. Igarasi, T. Fukahori: JAERI-1321 (1991).
5. N. Yamamuro: JAERI-M 90-006 (1990).
6. P.G. Young et al.: LA-12343-MS, UC-413 ( 1992).
7. P.D. Kunz: Program Dwuck4, Computational Nuclear
Physics 2: Nuclear Reaction; edited by K. Langanke et al.,
published by Springer-Verlag (1992).
8. A.K.M. Harun-Ar-Rashid et al.: JAERI-CONF 2000-005, pp.131
(2000),
9. N. Yamano: Private communication.
10. M. Igashira: Private communication (2001).