(d, 3n) Reaction cross-section calculation of some reactor materials.

Nuclear reactions with charged particles have applications in many fields such as radioisotope production, industrial applications, astrophysics, etc. Therefore, examining the excitation functions performed and obtained by the activation technique is also important for understanding the nature of nuclear reactions. Also, it is especially necessary to study these reactions to estimate the effects of radiation damage on the fusion structural materials used in the construction of the first walls and core of the reactor. In this study, cross-section data have been calculated theoretically to 45Sc (d, 3n)44Ti, 63Cu (d, 3n)62Zn, 89Y (d, 3n)88Zr, and 100Mo (d, 3n)99Tc reactions in the range of 1-50 MeV energy via ALICE/ASH, TALYS 1.95 and Empire 3.2.2 nuclear reaction codes. Optical Model Parameters (OMP) calculation for deuteron-induced reaction results has been performed via TALYS 1.95 code and the calculated cross-section values are reproduced well. Also, empirically developed (d, 3n) cross section formula (Kavun, 2020) calculations have been performed at 20 MeV energy. Finally, experimental EXFOR data was compared with all results and were found to be compatible with each other.

Investigation of (d, 3n) reaction cross section using theoretical nuclear codes calculations on some nuclear materials.

It is important to examine the effects of the nuclear reaction, which is used as a building material in nuclear reactors. Nuclear reactions occur as a result of the interaction between incident particles with the target nuclei. The charged particle-induced reactions have prime importance in understanding the reaction mechanism which can be applicable to understand the particles resulting from the reaction. It is useful to develop shielding the particle accelerators and fusion reactors. The present study contributes to providing the theoretical prediction of excitation functions for 112Cd (d, 3n)111In, 141Pr (d, 3n)140Nd, 167Er (d, 3n)166Tm, 197Au (d, 3n)196Hg and 209Bi (d, 3n)208Po reactions using theoretical model codes such as TALYS-1.95, EMPIRE-3.2.3, and ALICE-2014 within the incident deuteron energy range of threshold energy to 50 MeV. Also, newly developed (d, 3n) cross-section formula (Kavun, 2020) calculations have been performed for these reactions at 20 MeV of deuteron energy. Lastly, all calculated results have been compared with one another and with the previously published experimental data of the EXFOR database.

A new formulae study for the (n,2p) reaction cross-section systematics at 14-15 MeV.

The cross-section calculation systematics for nuclear reactions have great importance in describing the particle-induced excitation of nuclei. In this study, for 14-15 MeV of incident neutron energy, it has been suggested new empirical formulae to describe the (n, 2p) reactions cross sections. The new empirical formulae have been obtained for 29≤A≤159, 29≤A≤103 and 133≤A≤159 mass ranges which are dependent on s=(N-Z)/A asymmetry parameter. The asymmetry parameters have been obtained by modifying the original Levkovski formula. Then, EXFOR data has been studied by applying the least square fitting method and (n, 2p) reactions systematics has been revealed. The statistical dependence (R2) of these data was examined in the 29≤A≤159 total mass range. The calculated results from the obtained formulae have been compared with the literature data. The predictions of our formulae are in good agreement with the EXFOR data for 29≤A≤159 and 29≤A≤103 mass range.

The empirical cross section behavior of (d, 3n) reaction for 20±1.5 MeV energy.

Many nuclear reaction cross-section formalism has been developed for particle induced reaction up to date. In this study, a new empirical (d, 3n) cross section formulae systematic have been developed at 45≤A≤112 mass range for 20 ± 1.5 MeV incident deuterium energy. Also, (d, 3n) systematic have been grouped according to Even-N and Odd-Z numbers around 45≤A≤209 mass range. The Levkovskii asymmetry (N-Z/A) parameter have been used to improve empirical (d, 3n) cross section formula systemic. By using obtained new (d, 3n) empirical formulae systematics, theoretical (d, 3n) cross section calculations are made and the results have been found good agreement with the EXFOR data.