Sequential decay analysis of $^{235}$U(n$^{th}$,f) reaction using fragmentation approach

N. Sharma, Ashutosh Kaushik, Manoj K Sharma
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Abstract

Numerous experimental and theoretical observations conclude that the probability of the three fragment emission (ternary fission) or the binary fission increases when one proceeds towards the heavy mass region of nuclear periodic table. The collinear cluster tripartition (CCT) channel of $^{235}$U(n$^{th}$,f) reaction is studied and it was observed that the CCT may be a sequential process or a simultaneous emission phenomena. Till now, different approaches are introduced to study the CCT process as a simultaneous process or sequential process, but the decay dynamics of these modes is not fully explored. It will be of interest to identify the three fragments of the sequential process and to explore their related dynamics using some excitation energy dependent approach. Hence, in present work, an attempt is made to study the sequential decay mechanism of $^{235}$U(n$^{th}$,f) reaction using quantum mechanical fragmentation theory (QMFT). The decay mechanism is considered in two steps, where initially the nucleus splits into an asymmetric channel. In the second step, the heavy fragment obtained in the first step divides into two fragments. Stage I analysis is done by calculating the fragmentation potential and the preformation probability for the spherical and deformed choice of the decaying fragments. The most probable fragment combination of stage I are identified in view the dips in the fragmentation structure, and the corresponding maxima's of the preformation probability ($P_0$). The excitation energy of the decay channel is calculated using an iteration process. The obtained excitation energy of the identified heavy fragments is further used for the fragmentation analysis, and the subsequent binary fragments of the sequential process are obtained. The identified three fragments of the sequential process are in agreement with the experimental observation and are found nearby the neutron or proton shell closure. Finally, the kinetic energy of the observed fragments is calculated and the middle fragment of the CCT mechanism is identified.
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利用碎片法对 $^{235}$U(n$^{th}$,f) 反应进行序列衰变分析
大量实验和理论观察得出的结论是,当向核元素周期表的重质量区移动时,三个碎片发射(三元裂变)或二元裂变的概率会增加。对 $^{235}$U(n$^{th}$,f) 反应的共线簇三分裂(CCT)通道进行了研究,发现 CCT 可能是一个顺序过程,也可能是一个同时发射现象。到目前为止,人们已经引入了不同的方法来研究 CCT 过程是同步过程还是顺序过程,但这些模式的衰变动力学还没有得到充分的探讨。利用一些与激发能量相关的方法来识别顺序过程的三个片段并探索它们的相关动力学将是很有意义的。因此,本研究尝试利用量子力学碎片理论(QMFT)研究 $^{235}$U(n$^{th}$,f) 反应的顺序衰变机制。衰变机制分为两步:第一步,原子核分裂成不对称通道。在第二步中,第一步得到的重碎片分裂成两个碎片。第一阶段的分析是通过计算衰变碎片的球形和变形选择的碎片势能和预形成概率来完成的。第一阶段最可能的碎片组合是根据碎片结构的凹点和相应的预形成概率($P_0$)的最大值确定的。通过迭代过程计算衰变通道的激发能量。所获得的已识别重碎片的激发能量将进一步用于碎片分析,并获得序列过程的后续二进制碎片。所确定的序列过程的三个碎片与实验观测结果一致,并在中子或质子壳闭合附近被发现。最后,计算了观测到的碎片的动能,并确定了 CCT 机制的中间碎片。
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