Your search keyword '"Zeen Yao"' showing total 4 results

1. Evaluation of pre-neutron-emission mass distributions of neutron-induced typical actinide fission using scission point model *

Author

Yu Zhang, Xu Yang, Chang-Qi Liu, Kang Wu, Chao Han, Yuan He, Qin Xie, Junrun Wang, Zheng Wei, Xing-Yu Liu, Zeen Yao, Chang Huang, Xiao-Dong Su, Dong-Ying Huo, and Xiao-Jun Bao

Subjects

Physics, Nuclear and High Energy Physics, Nuclear transmutation, Fission, Neutron emission, Nuclear Theory, Astronomy and Astrophysics, Actinide, Nuclear physics, Semi-empirical mass formula, Nuclear fission, Neutron, Nuclear Experiment, Instrumentation, Excitation

Abstract

The scission point model is improved by considering the excitation-dependent liquid drop model to calculate mass distributions for neutron-induced actinide nuclei fission. Excitation energy effects influence the deformations of light and heavy fragments. The improved scission point model shows a significant advance with regard to accuracy for calculating pre-neutron-emission mass distributions of neutron-induced typical actinide fission with incident-neutron-energies up to 99.5 MeV. The theoretical frame assures that the improved scission point model is suitable for evaluating the fission fragment mass distributions, which will provide guidance for studying fission physics and designing nuclear fission engineering and nuclear transmutation systems.

Published

2021

2. Measurements of neutron energy spectra of 9Be(d,n)10B reaction with a thick beryllium target *

Author

Dong-Ying Huo, Chang-Qi Liu, Xiao-Hou Bai, Kai Zhang, Shuang-Jiao Zhang, Rui Guo, Yu Zhang, Chao Han, Chang Huang, Kang Wu, Yan-Yan Ding, Zhi-Yong Deng, Zeen Yao, Qin Xie, Zhi-Jie Hu, Yang-Bo Nie, Zhi-Ming Hu, and Zheng Wei

Subjects

Physics, Nuclear and High Energy Physics, 010308 nuclear & particles physics, Branching fraction, Neutron emission, chemistry.chemical_element, Astronomy and Astrophysics, 01 natural sciences, Neutron temperature, chemistry, Deuterium, Excited state, 0103 physical sciences, ComputingMethodologies_DOCUMENTANDTEXTPROCESSING, Neutron, Beryllium, Atomic physics, 010306 general physics, Ground state, Instrumentation

Abstract

Novel measurements of the neutron energy spectra of the 9Be(d,n)10B reaction with a thick beryllium target are performed using a fast neutron time-of-flight (TOF) spectrometer for the neutron emission angles and , and the incident deuteron energies are 250 and 300 keV, respectively. The neutron contributions from the 9Be(d,n)10B reaction are distributed relatively independently for the ground state and the first, second, and third excited states of 10B. The branching ratios of the 9Be(d,n)10B reaction for the different excited states of 10B are obtained for the neutron emission angles and , and the incident deuteron energies are 250 and 300 keV, respectively. The branching ratio of the 9Be(d,n)10B reaction for the third excited state decreases with increase in the incident deuteron energy, and the branching ratios for the ground state and the second excited state increase with increase in the neutron emission angle.

Published

2021

3. Monte Carlo simulation of fast neutron-induced fission of 237Np *

Author

Xiao-Dong Su, Huang Zhiwu, Xiao-Hou Bai, Yu Zhang, Ma Zhanwen, Wei-Min Li, Dapeng Xu, Zheng Wei, Chang-Qi Liu, Shuang-Jiao Zhang, Junrun Wang, Xiao-Long Lu, Zeen Yao, Shao-Hua Peng, Chang Huang, and Chao Han

Subjects

Physics, Nuclear and High Energy Physics, Nuclear transmutation, 010308 nuclear & particles physics, Fission, Monte Carlo method, Astronomy and Astrophysics, Actinide, Kinetic energy, 01 natural sciences, Nuclear physics, Distribution (mathematics), Yield (chemistry), 0103 physical sciences, Neutron, 010306 general physics, Instrumentation

Abstract

The potential-driving model is used to describe the driving potential distribution and to calculate the pre-neutron emission mass distributions for different incident energies in the reaction. The potential-driving model is implemented in Geant4 and used to calculate the fission-fragment yield distributions, kinetic energy distributions, fission neutron spectrum and the total nubar for the reaction. Compared with the built-in G4ParaFissionModel, the calculated results from the potential-driving model are in better agreement with the experimental data and evaluated data. Given the good agreement with the experimental data, the potential-driving model in Geant4 can describe well the neutron-induced fission of actinide nuclei, which is very important for the study of neutron transmutation physics and the design of a transmutation system.

Published

2019

4. Calculation of the wide-angle neutron spectra from the 9Be(d, xn) reaction in a thick beryllium target *

Author

Xiao-Long Lu, Zeen Yao, Ma Zhanwen, Yan-Yan Ding, Jian-Yi Li, Jie Zhang, Lei Yang, Junrun Wang, Dapeng Xu, Li Xia, Zheng Wei, Yu Zhang, Yaling Zhang, and Huang Zhiwu

Subjects

Nuclear and High Energy Physics, Materials science, chemistry, Nuclear Theory, chemistry.chemical_element, Neutron source, Astronomy and Astrophysics, Neutron spectra, Atomic physics, Beryllium, Nuclear Experiment, Instrumentation

Abstract

The multi-layer computing model is developed to calculate wide-angle neutron spectra, in the range from 0° to 180° with a 5° step, produced by bombarding a thick beryllium target with deuterons. The double-differential cross-sections (DDCSs) for the 9Be(d, xn) reaction are calculated using the TALYS-1.8 code. They are in agreement with the experimental data, and are much better than the PHITS-JQMD/GEM results at 15° , 30° , 45° and 60° neutron emission angles for deuteron energy of 10.0 MeV. In the TALYS-1.8 code, neutron contributions from direct reactions (break-up, stripping and knock-out reactions) are controlled by adjustable parameters, which describe the basic characteristics of typical direct reactions and control the relative intensity and the position of the ridgy hillock at the tail of DDCSs. It is found that the typical calculated wide-angle neutron spectra for different neutron emission angles and neutron angular distributions agree quite well with the experimental data for 13.5 MeV deuterons. The multi-layer computing model can reproduce the experimental data reasonably well by optimizing the adjustable parameters in the TALYS-1.8 code. Given the good agreement with the experimental data, the multi-layer computing model could provide better predictions of wide-angle neutron energy spectra, neutron angular distributions and neutron yields for the 9Be(d, xn) reaction neutron source.

Published

2019