___

• [1] Beghian, LE; Halban, HH. Absolute Cross-sections for the Capture of Neutrons of 200 and 900 keV. Energy. Nature. 1949; 163, 366-367.
• [2] Macklin, RL; Gibbons, JH. Capture-cross-section studies for 30—220-keV neutrons using a new technique. Phys. Rev. 1967; 159, (4), 1007.
• [3] Browne, JC; Berman, BL. Neutron-Capture Cross Sections for Te 128 and Te 130 and the Xenon Anomaly in Old Tellurium Ores. Phys. Rev. C 1973; 8, (6), 2405.
• [4] Wisshak, K; Voss, F; Kappeler, F; Reffo, G. Neutron capture in Te 122, 123, 124: Critical test for s process studies. Phys. Rev. C 1992; 45, (5), 2470.
• [5] Xia, Y; Gerstenhofer, Th W; Jaag, S; Kappeler, F; Wisshak, K. Neutron cross sections of Te 122, Te 123, and Te 124 between 1 and 60 keV. Phys. Rev. C 1992; 45, (5), 2487.
• [6] Tomandl, I; Honzatko, J; Von Egidy, T; Wirth, H-F; Belgya, T; Lakatos, M; Szentmiklosi, L; Revay, Zs, Molnar, GL; Firestone, RB ve diğerleri. Phys. Rev. C 2003; 68, (6), 067602.
• [7] Von Egidy, T; Wirth, H-F; Tomandl, I; Honzatko, J. Phys. Rev. C 2006; 74, (3), 034319.
• [8] Wirth, H-F; Von Egidy, T; Tomandl, I; Honzatko, J ; Bucurescu, D; Marginean, N; Ponomarev, V Yu ; Hertenberger, R; Eisermann, Y; Graw, G. Nucl. Phys. A 2003; 716, 3-54.
• [9] Honzatko, J; Bondarenko, V; Tomandl, I; Von Egidy, T ; Wirth, H-F; Bucurescu, D; Ponomarev, V Yu; Marginean, N; Hertenberger, R; Eisermann, Y ve diğerleri. Nucl. Phys. A 2005; 756, (3), 249-307.
• [10] Iachello, F; Scholten, O. Interacting boson-fermion model of collective states in odd-A nuclei. Phys. Rev. Lett. 1979; 43, (10), 679.
• [11] Soloviev, Vadim G. Theory of Atomic Nuclei, Quasi-particle and Phonons. CRC Press 1992.
• [12] Kirsten, T; Richter, H; Jessberger, EK. Double beta decay of 128Te and 130Te: Improved limit on the neutrino restmass. Zeitschrift fur Physik C Particles and Fields. 1983; 16, (3), 189-196.
• [13] Richardson, JF; Manuel, OK; Sinha, B; Thorpe, RI. Double beta decay of tellurium-130. Nucl . Phys. A 1986; 453, (1), 26-44.
• [14] Lin, WJ; Manuel, OK; Oliver, LL; Thorpe, RI. Double beta-decay of 82Se and 130Te. Nucl. Phys. A 1986; 457, (2), 285-291.
• [15] Lin, Wuu-Jyh; Manuel, OK; Muangnoicharoen, Sirinart; Thorpe, RI. Double beta-decay of tellurium-128 and tellurium-130. Nucl. Phys. A 1988; 481, (3), 484-493.
• [16] Lee, Jauh-Tzuoh; Manuel, OK; Thorpe, RI. Ratio of double beta-decay rates of 128,130 Te. Nucl. Phys. A 529, (1), 29-38.
• [17] Hennecke, EW; Manuel, OK; Sabu, DD. Double beta decay of Te 128. Phys. Rev. C 1975; 11,(4), 1378.
• [18] Bernatowicz, T; Brannon, J; Brazzle, R; Cowsik, R ; Hohenberg, C; Podosek, F. Precise determination of relative and absolute betabeta-decay rates of Te 128 and Te 130. Phys. Rev. C 1993; 47, (2), 806.
• [19] De Laeter, JR; Smith, CL; Rosman, KJR. Critical role of Te 122, 123, 124 in s-process nucleosynthesis. Phys. Rev. C 1994; 49, (2), 1227.
• [20] Kappeler, Franz; Gallino, Roberto; Bisterzo, Sara ; Aoki, Wako. The s process: Nuclear physics, stellar models, and observations. Rev. of Mod. Phys. 2011; 83, (1), 157.
• [21] Takahashi, K; Blaum, Klaus; Novikov, Yu. Synthesis of the S-only 122,123,124 Te Isotopes and the Selective Depletion of 123Te by Electron Capture Process in Massive Stars. The Astrophysical Journal. 2016; 819, (2), 118.
• [22] Naito, S; Tomyo, A; Shima, T; Kii, T; Baba, T ; Takahashi, T; Nagai, Y. KENS keV neutron flux for nuclear astrophysics. Nucl. Inst. and Meth. in Phys. Res. Sec. A. 1999; 423, (2), 404-413.
• [23] Xu, Yi; Goriely, Stephane; Koning, Arjan J; Hilaire, Stephane. Systematic study of neutron capture including the compound, pre-equilibrium, and direct mechanisms. Phys. Rev. C 2014; 90, (2), 024604.
• [24] Gilbert A; Cameron AG. A composite nuclear-level density formula with shell corrections. Canadian Journal of Physics. 1965; 43, (8), 1446-1496.
• [25] Bethe, H. A. Nuclear Physics B. Nuclear Dynamics, Theoretical. Rev. Mod. Phys. 1937; 9, 69.
• [26] Dilg, W. ve ark. Level density parameters for the back-shifted fermi gas model in the mass range 40
• [27] Ignatyuk, A. V; Istekov, K. K; Smirenkin, G. N. Collective effects in level density, and the probability of fission. Sov. J. Nucl. Phys. 1979; 30, (5).
• [28] Ignatyuk, A. V; Weil J. L; Raman S; Kahane S. Density of discrete levels in Sn 116. Phys. Rev. C. 1993; 47, (4), 1504.
• [29] Goriely, S; Tondeur, F; Pearson, J. M. Atom. Data Nucl. Data Tables 2001; 77, 311.
• [30] Goriely, S; Hilaire, S; Koning, A. J. Improved microscopic nuclear level densities within the HFB plus combinatorial method. Phys. Rev. C 2008; 78, 064307.
• [31] Hilaire, S; Girod, M; Goriely, S; Koning, A. J. Temperature dependent combinatorial level densities with the D1M Gogny force. Phys. Rev. C 2012; 86, 064317.
• [32] Kopecky, J; Uhl, M. Test of gamma-ray strength functions in nuclear reaction model calculations. Phys. Rev. C 1990; 41, 1941.
• [33] Brink, D. M. Individual particle and collective aspects of the nuclear photoeffect. Nucl. Phys. 1957; 4, 215.
• [34] Axel, P. Electric dipole ground-state transition width strength function and 7-Mev photon interactions. Phys. Rev. 1962; 126, 671.
• [35] R. Capote, R; Herman, M;. Oblozinsky, P; Young, P. G; Goriely, S; Belgya, T; Ignatyuk, A. V; Koning, A. J; Hilaire, S; Plujko, V; Avrigeanu, M; Bersillon, O; Chadwick, M. B; Fukahori, F; Kailas, S. ve diğerleri. RIPL-reference input parameter library for calculation of nuclear reactions and nuclear data evluations. Nucl. Data Sheets 2009; 110, 3107.
• [36] Goriely, S. Radiative neutron captures by neutron-rich nuclei and the r-process nucleosynthesis. Phys. Lett. B 1998; 436,10.
• [37] A.J. Koning, A. J;. Hilaire, S; Duijvestijn, M. C. TALYS-1.0. EDP Sciences, 2008; 211-214.