刘星泉，博士，研究员。2010年毕业于吉林大学物理学院；2015年于中国科学院近代物理研究所获理学博士学位，博士论文入选“2016年度中科院优秀博士学位论文”；2015-2019年在中国科学院近代物理所重离子核反应组工作，2017年起任副研究员；2019年至今在四川大学核科学与技术研究所工作，任研究员；2012和2013年在美国德克萨斯农业机械大学回旋加速器中心访问学习，2017和2018年在德国达姆施塔特重离子研究所（GSI）做博士后。2019入选四川大学“校百人计划B”； 2020年入选四川省“千人计划”，获“四川省特聘专家”称号。以第一或通讯作者在PLB、PRC等国内外期刊发表论文22篇；主持国家自然科学基金2项、中科院“西部之光”人才计划基金1项，并参与多项不稳定核结构性质研究方向相关的课题。

主要研究领域：

       1. 中低能区重离子核反应动力学

       2. 亚饱和密度区核物质状态方程

       3. 质子散射探针精确测量原子核物质分布及半径

       4. 垒上弱束缚核弹性散射

       5. 中子核数据评价及反应堆中子物理

Professor, Ph.D.

Institute of Nuclear Science and Technology, Sichuan University

Chengdu 610064

P.R. China

E-mail：liuxingquan@scu.edu.cn

Education                                           

2010/9 - 2015/7, Institute of Modern Physics, Chinese Academy of Sciences, PhD

2006/9 - 2010/7, Jilin University, Bachelor

Interests

       1. Dynamics of the heavy-ion reactions at Fermi energy region

       2. Nuclear equation of state at sub-saturation densities

       3. Probing nuclear density and radius using elastic proton scatterings

       4. Elastic scattering of weakly bound nuclei above Coulomb barrier

       5. Neutron data benchmark and neutron physics in nuclear reactor

代表性论文Publications

(1) Determining the nuclear temperature dependence on source neutron-proton asymmetry in heavy-ion reactions at intermediate energy, Chinese Physics C, 2023, 47: 054002.

(2) Determining impact parameters of heavy-ion collisions at low-intermediate incident energies using deep learning with convolutional neural networks, Physical Review C, 2022, 105: 034611.

(3) Experimental investigation of abnormal transverse flow enhancement of α particles in heavy-ion collisions, Physical Review C, 2021, 104: 044611.

(4) Nuclear matter density distributions of the neutron-rich 6,8He isotopes from a sum-of-Gaussian analysis of elastic proton scattering data at intermediate energies, Physical Review C, 2021, 104: 034315.

(5) Abnormal flow of α particles in heavy-ion collisions at intermediate energies, Physical Review C, 2021, 103: 044607.

(6) Nuclear temperature and its dependence on the source neutron-proton asymmetry deduced using the Albergo thermometer, Physical Review C, 2021, 103: 014601.

(7) Investigation of the nuclear liquid-gas phase transition in the static AMD, Journal of Physics G: Nuclear and Particle Physics, 2021, 48: 085103.

(8) Variance in the radial distribution of nuclear matter between 56Ni and 58Ni inferred from a model-independent Sum-of-Gaussian analysis of elastic proton scattering data, Physics Letters B, 2020, 809: 135776.

(9) Probing the neutron-proton asymmetry dependence of the nuclear source temperature with light charged particles, Physical Review C, 2020, 101: 064603.

(10) Neutron-proton asymmetry dependence of nuclear temperature with intermediate mass fragments, Physical Review C, 2019, 99: 064601.

(11) Solidarity of signal of measures for the liquid-gas phase transition in the statistical multifragmentation model, Physical Review C, 2019, 99: 054616.

(12) Sensitivity study of experimental measures for the nuclear liquid-gas phase transition in the statistical multifragmentation model, Physical Review C, 2018, 97: 054615.

(13) Statistical analysis of experimental multifragmentation events in 64Zn+112Sn at 40 MeV/nucleon, Physical Review C, 2018, 97: 044603.

(14) Reexamination of a novel determination of density, temperature, and symmetry energy based on a modified Fisher model, Physical Review C, 2018, 97: 014613.

(15) Z-dependence Flow Pattern and Experimental Filter Effect on transverse Flow Extraction in Intermediate-energy Heavy Ion Collisions, Nuclear Physics Review, 2018, 35: 1.

(16) Chemical potential and symmetry energy for intermediate-mass fragment production in heavy ion reactions near the Fermi energy, Physical Review C, 2017, 95: 044601.

(17) High-energy proton emission and Fermi motion in intermediate-energy heavy-ion collisions, Physical Review C, 2016, 94: 064609.

(18) Investigation on symmetry and characteristic properties of the fragmenting source in heavy-ion reactions through reconstructed primary isotope yields, Nuclear Science and Techniques, 2016, 27: 131.

(19) Reconstructed primary fragments and symmetry energy, temperature and density of the fragmenting source in 64Zn+112Sn at 40MeV/nucleon, Nuclear Physics A, 2015, 933: 290-305.

(20) Freezeout concept and dynamical transport model in intermediate-energy heavy-ion reactions, Physical Review C, 2015, 92: 014623.

(21) Symmetry energy extraction from primary fragments in intermediate heavy-ion collisions, Nuclear Science and Techniques, 2015, 26: S20508.

(22) Mass dependence of transverse flow in heavy ion collisions at intermediate energies, Physical Review C, 2014, 90: 014604.

(23) Primary isotope yields and characteristic properties of the fragmenting source in heavy-ion reactions near the Fermi energy, Physical Review C, 2014, 90: 014605.