52-Te-128
52-Te-128 JNDC EVAL-MAR90 JNDC FP NUCLEAR DATA W.G.
DIST-MAY10 20091216
----JENDL-4.0 MATERIAL 5249
-----INCIDENT NEUTRON DATA
------ENDF-6 FORMAT
===========================================================
JENDL-3.2 data were automatically transformed to JENDL-3.3.
Interpolation of spectra: 22 (unit base interpolation)
(3,251) deleted, T-matrix of (4,2) deleted, and others.
===========================================================
History
84-10 Evaluation for JENDL-2 was made by JNDC FPND W.G./1/
90-03 Modification for JENDL-3 was made/2/.
09-12 Compiled by A.Ichihara.
***** modified parts for JENDL-4.0 ********************
(2,151) Resolved resonance parameters were revised
by K.Shibata.
***********************************************************
mf = 1 General information
mt=451 Comments and dictionary
mf = 2 Resonance parameters
mt=151 Resolved and unresolved resonance parameters
Resolved resonance region (MLBW formula) : below 8 keV
Neutron widths were adopted from experimental data of
Tellier et al./3/, and radiative capture widths from
capture areas measured by Browne and Berman/4/. For the
resonances above 7 keV, the average radiation width of 0.048
+-0.025 eV was assumed. A negative resonance was added at
-600 eV so as to reproduce the thermal capture cross section
of 0.215+-0.008 barns/5/. The effective scattering radius
of 5.5 fm was taken from ref./5/
In JENDL-4, the radiation width of the negative resonance
was changed to 166.4 meV so as to reproduce the thermal
capture cross section measured by Wirth et al./6/
Unresolved resonance region : 8 keV - 100 keV
The neutron strength function S0 was based on the compilation
of Mughabghab et al./5/, and S1 and S2 were calculated with
optical model code CASTHY/7/. The observed level spacing was
determined to reproduce the capture cross section calculated
with CASTHY. The effective scattering radius was obtained
from fitting to the calculated total cross section at 100 keV.
The radiation width Gg was based on the systematics of
measured values for neighboring nuclides.
Typical values of the parameters at 70 keV:
S0 = 0.250e-4, S1 = 1.700e-4, S2 = 1.000e-4, Sg = 0.540e-4,
Gg = 0.150 eV, R = 5.897 fm.
The unresolved resonance parameters should be used only for
self-shielding calculation.
Thermal cross sections and resonance integrals at 300 K
----------------------------------------------------------
0.0253 eV res. integ. (*)
(barns) (barns)
----------------------------------------------------------
Total 4.302E+00
Elastic 4.115E+00
n,gamma 1.861E-01 1.29E+00
----------------------------------------------------------
(*) Integrated from 0.5 eV to 10 MeV.
mf = 3 Neutron cross sections
Below 8 keV, resolved resonance parameters were given.
The spherical optical and statistical model
calculation was performed with CASTHY, by taking account of
competing reactions, of which cross sections were calculated
with PEGASUS/8/ standing on a preequilibrium and multi-step
evaporation model. The OMP's for neutron given in Table 1 were
determined to reproduce a systematic trend of the total cross
section by changing r0 and rso of Iijima-Kawai potential/9/.
The OMP's for charged particles are as follows:
proton = Perey/10/
alpha = Huizenga and Igo/11/
deuteron = Lohr and Haeberli/12/
helium-3 and triton = Becchetti and Greenlees/13/
Parameters for the composite level density formula of Gilbert
and Cameron/14/ were evaluated by Iijima et al./15/ More
extensive determination and modification were made in the
present work. Table 2 shows the level density parameters used
in the present calculation. Energy dependence of spin cut-off
parameter in the energy range below E-joint is due to Gruppelaar
/16/.
mt = 1 Total
Spherical optical model calculation was adopted.
mt = 2 Elastic scattering
Calculated as (total - sum of partial cross sections).
mt = 4, 51 - 91 Inelastic scattering
Spherical optical and statistical model calculation was
adopted. The level scheme was taken from Ref./17/.
no. energy(MeV) spin-parity
gr. 0.0 0 +
1 0.7432 2 +
2 1.4971 4 +
3 1.5232 2 +
4 1.8111 6 +
5 1.9722 2 +
6 1.9822 0 +
7 2.0300 4 +
8 2.1320 2 +
9 2.1335 5 -
Levels above 2.197 MeV were assumed to be overlapping.
mt = 102 Capture
Spherical optical and statistical model calculation with
CASTHY was adopted. Direct and semi-direct capture cross
sections were estimated according to the procedure of Benzi
and Reffo/18/ and normalized to 1 milli-barn at 14 MeV.
The gamma-ray strength function (4.85e-05) was adjusted to
reproduce the capture cross section of 48 milli-barns at 20
keV measured by Bergman and Romanov/19/.
mt = 16 (n,2n) cross section
mt = 17 (n,3n) cross section
mt = 22 (n,n'a) cross section
mt = 28 (n,n'p) cross section
mt =103 (n,p) cross section
mt =104 (n,d) cross section
mt =105 (n,t) cross section
mt =107 (n,alpha) cross section
These reaction cross sections were calculated with the
preequilibrium and multi-step evaporation model code PEGASUS.
The Kalbach's constant k (= 116.8) was estimated by the
formula derived from Kikuchi-Kawai's formalism/20/ and level
density parameters.
Finally, the (n,p) and (n,alpha) cross sections were
normalized to the following values at 14.5 MeV:
(n,p) 2.40 mb (recommended by Forrest/21/)
(n,alpha) 0.95 mb (recommended by Forrest)
mt = 251 mu-bar
Calculated with CASTHY/7/.
mf = 4 Angular distributions of secondary neutrons
Legendre polynomial coefficients for angular distributions are
given in the center-of-mass system for mt=2 and discrete inelas-
tic levels, and in the laboratory system for mt=91. They were
calculated with CASTHY. For other reactions, isotropic distri-
butions in the laboratory system were assumed.
mf = 5 Energy distributions of secondary neutrons
Energy distributions of secondary neutrons were calculated with
PEGASUS for inelastic scattering to overlapping levels and for
other neutron emitting reactions.
TABLE 1 NEUTRON OPTICAL POTENTIAL PARAMETERS
DEPTH (MEV) RADIUS(FM) DIFFUSENESS(FM)
---------------------- ------------ ---------------
V = 45.97-0.199E R0 = 6.481 A0 = 0.62
WS = 6.502 RS = 6.926 AS = 0.35
VSO= 7.0 RSO= 6.49 ASO= 0.62
THE FORM OF SURFACE ABSORPTION PART IS DER. WOODS-SAXON TYPE.
TABLE 2 LEVEL DENSITY PARAMETERS
NUCLIDE A(1/MEV) T(MEV) C(1/MEV) EX(MEV) PAIRING
---------------------------------------------------------------
50-SN-124 1.601E+01 6.160E-01 3.224E-01 6.294E+00 2.280E+00
50-SN-125 1.591E+01 6.210E-01 1.927E+00 5.249E+00 1.190E+00
50-SN-126 1.646E+01 6.270E-01 4.012E-01 6.778E+00 2.390E+00
50-SN-127 1.577E+01 6.140E-01 1.633E+00 5.075E+00 1.190E+00
51-SB-125 1.700E+01 5.120E-01 7.883E-01 3.792E+00 1.090E+00
51-SB-126 1.700E+01 5.250E-01 7.566E+00 2.897E+00 0.0
51-SB-127 1.700E+01 5.120E-01 6.326E-01 3.902E+00 1.200E+00
51-SB-128 1.468E+01 5.600E-01 4.264E+00 2.658E+00 0.0
52-TE-126 1.706E+01 6.100E-01 5.154E-01 6.554E+00 2.230E+00
52-TE-127 2.004E+01 5.380E-01 3.633E+00 5.165E+00 1.140E+00
52-TE-128 1.800E+01 6.090E-01 6.586E-01 7.010E+00 2.340E+00
52-TE-129 2.015E+01 5.350E-01 3.588E+00 5.141E+00 1.140E+00
---------------------------------------------------------------
Spin cutoff parameters were calculated as 0.146*sqrt(a)*a**(2/3).
In the CASTHY calculation, spin cutoff factors at 0 MeV were
assumed to be 7.680 for Te-128 and 5.913 for Te-129.
References
1) Aoki, T. et al.: Proc. Int. Conf. on Nuclear Data for Basic
and Applied Science, Santa Fe., Vol. 2, p.1627 (1985).
2) Kawai, M. et al.: Proc. Int. Conf. on Nuclear Data for Science
and Technology, Mito, p. 569 (1988).
3) Tellier, H., et al.: CEA-N-1268 (1970).
4) Browne, J.C., Berman, B.L.: Phys. Rev., C8, 2405 (1973).
5) Mughabghab, S.F. et al.: "Neutron Cross Sections, Vol. I,
Part A", Academic Press (1981).
6) Wirth, H.-F. et al.: Nucl. Phys., A716, 3 (2003).
7) Igarasi, S.: J. Nucl. Sci. Technol., 12, 67 (1975).
8) Iijima, S. et al.: JAERI-M 87-025, p. 337 (1987).
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(1983).
10) Perey, F.G: Phys. Rev. 131, 745 (1963).
11) Huizenga, J.R. and Igo, G.: Nucl. Phys. 29, 462 (1962).
12) Lohr, J.M. and Haeberli, W.: Nucl. Phys. A232, 381 (1974).
13) Becchetti, F.D., Jr. and Greenlees, G.W.: Polarization
Phenomena in Nuclear Reactions ((Eds) H.H. Barshall and
W. Haeberli), p. 682, the University of Wisconsin Press.
(1971).
14) Gilbert, A. and Cameron, A.G.W.: Can. J. Phys., 43, 1446
(1965).
15) Iijima, S., et al.: J. Nucl. Sci. Technol. 21, 10 (1984).
16) Gruppelaar, H.: ECN-13 (1977).
17) Matsumoto, J.: private communication (1981).
18) Benzi, V. and Reffo, G.: CCDN-NW/10 (1969).
19) Bergman, A.A. and Romanov, S.A.: Yadernaya Fizika, 20, 252
(1974).
20) Kikuchi, K. and Kawai, M.: "Nuclear Matter and Nuclear
Reactions", North Holland (1968).
21) Forrest, R.A.: AERE-R 12419 (1986).