李志攀:山东曹县人,博士,研究员。2005年获兰州大学理学学士学位,2010年获北京大学粒子物理与原子核物理专业理学博士学位,随后就职西南大学工作至今,先后任特聘教授、研究员。2007年至今曾先后访问美国橡树岭国家实验室、德国慕尼黑工业大学、法国IPN-Orsay 研究所、克罗地亚萨格勒布大学等。
目前主要从事相对论量子多体理论、奇特原子核谱学与新奇物理现象、原子核裂变等方面的研究工作。已在国际著名期刊Physical Review系列、Physics Letters B等发表论文近80篇,总引用1700余次。先后主持国家自然科学基金、科技部政府间科技合作项目等9个基础科研项目。2018年入选重庆市高层次人才特殊支持计划青年拔尖人才,2020年入选国家级青年人才项目。主要承担《理论力学》、《力学》、《大学物理》(双语)、《密度泛函理论与程序设计》等课程的教学任务。
Email :zpliphy@swu.edu.cn
主要研究方向:
相对论密度泛函理论发展及应用;
奇特原子核谱学与新奇物理现象;
原子核裂变;
主持的科研项目或人才项目:
2020年入选国家级青年人才项目
2018年入选重庆市高层次人才特殊支持计划第四批青年拔尖人才
霍英东教育基金会第十七届高等院校青年教师基金:原子核裂变的微观理论研究;2020.2-2023.2
国家自然科学基金-面上项目(11875225):原子核裂变动力学的协变密度泛函理论研究;60万元;2019.1-2022.12
国家自然科学基金-面上项目(11475140):原子核低激发谱与量子相变的协变密度泛函研究;80万元;2015.1-2018.12
国家自然科学基金-青年项目(11105110):基于协变密度泛函理论微观研究原子核量子相变;22万元;2012.1-2014.12
科技部中国-克罗地亚政府间科技合作项目:原子核裂变动力学的微观能量密度泛函研究;2015.7-2017.6
科技部中国-克罗地亚政府间科技合作项目:奇特原子核结构及相关热点物理的研究;2014.1-2015.12
重庆市自然科学基金项目(cstc2011jjA0376):丰质子原子核中新型不对称裂变的研究;2012.1-2014.12
中央高校基本科研业务费专项资金(XDJK2011B002):奇A原子核量子相变与临界点对称性的微观研究;2011.5- 2014.5
西南大学博士基金(SWU110039):极化质子-奇特原子核反应的微观研究;2010.10-2013.10
发表的学术论文详见ResearcherID:F-6299-2012
1、Topical Review: Michael Bender, Remi Bernard, George Bertsch, Satoshi Chiba, Jacek Dobaczewski, Noël Dubray, Samuel A Giuliani, Kouichi Hagino, Denis Lacroix, Zhipan Li, Piotr Magierski, Joachim Maruhn, Witold Nazarewicz, Junchen Pei, Sophie Peru, Nathalie Pillet, Jørgen Randrup, David Regnier, Paul-Gerhard Reinhard, Luis M Robledo, Wouter Ryssens, Jhilam Sadhukhan, Guillaume Scamps, Nicolas Schunck, Cedric Simenel, Janusz Skalski, Ionel Stetcu, Paul Stevenson, Sait Umar, Marc Verriere, Dario Vretenar, Michał Warda, and Sven Åberg, Future of nuclear fission theory, Journal of Physics G (2020), in press.
2、DRHBc Mass Table Collaboration, Deformed relativistic Hartree-Bogoliubov theory in continuum with a point-coupling functional: Examples of even-even Nd isotopes, Physical Review C 102, 024314 (2020).
3、J. Xiang, Z. P. Li*, T. Nikšić, D. Vretenar, and W. H. Long, Coupling of shape and pairing vibrations in a collective Hamiltonian based on nuclear energy density functionals, Physical Review C 101, 064301 (2020).
4、T. T. Sun*, L. Qian, C. Chen, P. Ring, and Z. P. Li*, Green's function method for the single-particle resonances in a deformed Dirac equation, Physical Review C 101, 014321 (2020).
5、L. Tan, Y. X. Liu, L. J. Wang, Z. P. Li, and Y. Sun, A novel method for stellar electron -capture rates of excited nuclear states, Physics Letters B 805, 135432 (2020).
6、C. Chen, Z. P. Li, Y. X. Li, and T. T. Sun, Single-particle resonant states with Green's function method, Chinese Physics C 44, 084105 (2020).
7、W. Sun, S. Quan, Z. P. Li*, J. Zhao, T. Nikšić, and D. Vretenar, Microscopic core-quasiparticle coupling model for spectroscopy of odd-mass nuclei with octupole correlations, Physical Review C 100, 044319 (2019).
8、J. Zhao, J. Xiang, Z. P. Li, T. Nikšić, D. Vretenar, and S.-G. Zhou, Time-dependent generator-coordinate-method study of mass-asymmetric fission of actinides, Physical Review C 99, 054613 (2019).
9、Z. Shi, A. Afanasjev, Z. P. Li, and J. Meng, Superheavy nuclei in a microscopic collective Hamiltonian approach: The impact of beyond-mean-field correlations on ground state and fission properties, Physical Review C 99, 064316 (2019).
10、S. N. T. Majola, Z. Shi, B. Y. Song, Z. P. Li, et. al., beta and gamma bands in N=88, 90, and 92 isotones investigated with a five-dimensional collective Hamiltonian based on covariant density functional theory: Vibrations, shape coexistence, and superdeformation, Physical Review C 100, 044324 (2019).
11、Z. Shi and Z. P. Li*, Microscopic description of triaxiality in Ru isotopes with covariant energy density functional theory, Physical Review C 97, 034329 (2018).
12、S. Quan, Z. P. Li*, D. Vretenar, and J. Meng, Nuclear quantum shape-phase transitions in odd-mass systems, Physical Review C (Rapid Communications) 97, 031301 (2018).
13、J. Xiang, Z. P. Li*, W. H. Long, T. Nikšić, and D. Vretenar, Shape evolution and coexistence in neutron-deficient Nd and Sm nuclei, Physical Review C 98, 054308 (2018).
14、Review: P. W. Zhao*, and Z. P. Li*, Spectroscopies of rod- and pear-shaped nuclei in covariant density functional theory, International Journal of Modern Physics E 27, 1830007 (2018).
15、S. Quan, W. P. Liu, Z. P. Li*, and M. S. Smith*, Microscopic core quasiparticle coupling model for spectroscopy of odd-mass nuclei, Physical Review C 96, 054309 (2017).
16、S. Quan, Q. Chen, Z. P. Li*, T. Nikšić, and D. Vretenar, Global analysis of quadrupole shape invariants based on covariant energy density functionals, Physical Review C 95, 054321 (2017).
17、H. Tao, J. Zhao, Z. P. Li*, T. Nikšić, and D. Vretenar, Microscopic study of induced fission dynamics of Th-226 with covariant energy density functionals, Physical Review C 96, 024319 (2017).
18、S. Y. Xia, H. Tao, Y. Lu, Z. P. Li*, T. Nikšić, and D. Vretenar, Spectroscopy of reflection-asymmetric nuclei with relativistic energy density functionals, Physical Review C 96, 054303 (2017).
19、Z. Xu and Z. P. Li*, Microscopic analysis of octupole shape transitions in neutron-rich actinides with relativistic energy density functional, Chinese Physics C 41, 124107 (2017).
20、E. F. Zhou, J. M. Yao, Z. P. Li, J. Meng, and P. Ring, Anatomy of molecular structures in Ne-20, Physics Letters B 753, 227 (2016).
21、Z. P. Li, T. Nikšić, and D. Vretenar, Coexistence of nuclear shapes: self-consistent mean-field and beyond, Journal of Physics G 43, 024005 (2016).
22、J. Xiang, J. M. Yao, Y. Fu, Z. H. Wang, Z. P. Li, and W. H. Long, Novel triaxial structure in low-lying states of neutron-rich nuclei around A approximate to 100, Physical Review C 93, 054324 (2016).
23、K. Q. Lu, Z. X. Li, Z. P. Li*, J. M. Yao, and J. Meng*, Global study of beyond-mean-field correlation energies in covariant energy density functional theory using a collective Hamiltonian method, Physical Review C 91, 027304 (2015).
24、X. D. Xu, S. S. Zhang*, A. J. Signoracci, M. S. Smith*, and Z. P. Li*, Analytical continuation from bound to resonant states in the Dirac equation with quadrupole-deformed potentials, Physical Review C 92, 024324 (2015).
25、Z. X. Li and Z. P. Li*, Center-of-mass correction and rotational correction in covariant density functional theory, Chinese Physics C 39, 114101 (2015).
26、Z. H. Wang, J. Xiang, W. H. Long*, and Z. P. Li*, Covariant density functional analysis of shape evolution in N=40 isotones, Journal of Physics G 42, 045108 (2015).
27、W. X. Xue, J. M. Yao, K. Hagino, Z. P. Li, H. Mei, and Y. Tanimura, Triaxially deformed relativistic point-coupling model for Lambda hypernuclei: A quantitative analysis of the hyperon impurity effect on nuclear collective properties, Physical Review C 91, 024327 (2015).
28、J. M. Yao, E. F. Zhou, and Z. P. Li, Beyond relativistic mean-field approach for nuclear octupole excitations, Physical Review C 92, 041304 (2015).
29、J. M. Yao, K. Hagino, Z. P. Li, J. Meng, and P. Ring, Microscopic benchmark study of triaxiality in low-lying states of 76Kr, Physical Review C 89, 054306 (2014).
30、X. Y. Wu, J. M. Yao, and Z. P. Li, Low-energy structure and anti-bubble effect of dynamical correlations in 46Ar, Physical Review C 89, 017304 (2014).
31、Q. S. Zhang, Z. M. Niu, Z. P. Li*, J. M. Yao*, and J. Meng*, Global dynamical correlation energies in covariant density functional theory: Cranking approximation, Frontiers of Physics 9, 529 (2014).
32、E. O. Lieder, R. M. Lieder, R. A. Bark, Q. B. Chen, S. Q. Zhang, J. Meng, E. A. Lawrie, J. J. Lawrie, S. P. Bvumbi, N. Y. Kheswa, S. S. Ntshangase, T. E. Madiba, P. L. Masiteng, S. M. Mullins, S. Murray, P. Papka, D. G. Roux, O. Shirinda, Z. H. Zhang, P. W. Zhao, Z. P. Li, J. Peng, B. Qi, S. Y. Wang, Z. G. Xiao, and C. Xu, Resolution of Chiral Conundrum in 106Ag: Doppler-Shift Lifetime Investigation, Physical Review Letters 112, 202502 (2014).
33、R. A. Bark, et al., Studies of chirality in the mass 80, 100 and 190 regions, International Journal of Modern Physics E 23, 8 (2014).
34、Z. P. Li, B. Y. Song, J. M. Yao, D. Vretenar, and J. Meng, Simultaneous quadrupole and octupole shape phase transitions in Thorium, Physics Letters B 726, 866 (2013).
35、J. M. Yao, H. Mei, and Z. P. Li, Does proton “bubble” structure exist in the low-lying states of 34Si, Physics Letters B 723, 459 (2013).
36、J. Xiang, Z. P. Li, J. M. Yao, W. H. Long, P. Ring, and J. Meng, Effect of pairing correlations on nuclear low-energy structure: BCS and general Bogoliubov transformation, Physical Review C 88, 057301 (2013).
37、W. Zhang*, Z. P. Li*, and S. Q. Zhang*, Description of alpha-decay chains for 293,294117 within covariant density functional theory, Physical Review C 88, 054324 (2013).
38、Y. Fu, H. Mei, J. Xiang, Z. P. Li, J. M. Yao, and J. Meng, Beyond relativistic mean-field studies of low-lying states in neutron-deficient krypton isotopes, Physical Review C 87, 054305 (2013).
39、K. Hagino, J. M. Yao, F. Minato, Z. P. Li, and M. T. Win, Collective excitations of Lambda hypernuclei, Nuclear Physics A 914, 151 (2013).
40、B. Y. Song, Z. P. Li*, J. M. Yao, and J. Meng, Energy density functional description of low-lying states in neutron-deficient Sn isotopes, Physica Scripta T154, 014012 (2013).
41、J. Meng, Y. Chen, H. Z. Liang, Y. F. Niu, Z. M. Niu, L. S. Song, P. W. Zhao, Z. Li, B. Sun, X. D. Xu, Z. P. Li, J. M. Yao, W. H. Long, T. Niksic, and D. Vretenar, Mass and lifetime of unstable nuclei in covariant density functional theory, Physica Scripta T154, 014010 (2013).
42、Z. P. Li, C. Y. Li, J. Xiang, J. M. Yao, and J. Meng, Enhanced collectivity in neutron-deficient Sn isotopes in energy functional based collective Hamiltonian, Physics Letters B 717, 470 (2012).
43、Z. P. Li, T. Nikšić, P. Ring, D. Vretenar, J. M. Yao, and J. Meng, Efficient method for computing the Thouless-Valatin inertia parameters, Physical Review C 86, 034334 (2012).
44、N. Hinohara, Z. P. Li, T. Nakatsukasa, T. Nikšić, and D. Vretenar, Effect of time-odd mean fields on inertial parameters of the quadrupole collective Hamiltonian, Physical Review C 85, 024323 (2012).
45、H. Mei, J. Xiang, J. M. Yao, Z. P. Li, and J. Meng, Rapid structural change in low-lying states of neutron-rich Sr and Zr isotopes, Physical Review C 85, 034321 (2012).
46、J. Xiang, Z. P. Li, Z. X. Li, J.M. Yao, J. Meng, Covariant description of shape evolution and shape coexistence in neutron-rich nuclei at N~60, Nuclear Physics A 873, 1 (2012).
47、H. Mei, Z. P. Li, J. M. Yao, and K. Hagino, Impurity effect of a hyperon on shape-coexistence nucleus S-44 in the energy functional based collective Hamiltonian, International Journal of Modern Physics E 21, 1250024 (2012).
48、Z. P. Li, J. M. Yao, D. Vretenar, T. Nikšić, and J. Meng, Energy Density Functional Analysis of Shape Coexistence in S-44, AIP Conference Proceedings Volume 1491, pp. 234-237 (2012).
49、Z. P. Li, J. M. Yao, T. Nikšić, D. Vretenar, H. Chen, and J. Meng, Energy density functional analysis of shape evolution in N=28 isotones, Physical Review C 84, 054304 (2011).
50、J. M. Yao, J. Meng, P. Ring, Z. X. Li, Z. P. Li, and K. Hagino, Microscopic description of quantum shape fluctuation in C isotopes, Physical Review C 84, 024306 (2011).
51、A. Krugmann, Z. P. Li, J. Meng, N. Pietralla and D. Vretenar, Comparison of the confined γ-soft Rotor Model and a microscopic collective Hamiltonian based on the relativistic mean field model in 150;152Nd, Journal of Physics G 38, 065102 (2011).
52、J. M. Yao, Z. P. Li, K. Hagino, M. T. Win, Y. Zhang, and J. Meng, Impurity effect of Lambda hyperon on collective excitations of nuclear core in Mg-25(Lambda), Nuclear Physics A 868, 12 (2011).
53、Z. P. Li, J. Xiang, J. M. Yao, H. Chen, and J. Meng, Sensitivity of the nuclear collectivity to the pairing strength in 150Nd, International Journal of Modern Physics E 20, 494-499 (2011).
54、C. Y. Song, Z. P. Li, D. Vretenar, and J. Meng, Microscopic analysis of spherical to γ-soft shape transitions in Zn isotopes, Science China-physics mechanics & astronomy 54, 222 (2011).
55、Z. P. Li, T. Nikšić, D. Vretenar, and J. Meng, Microscopic Description of Spherical to γ-soft Shape Transitions in Ba and Xe Nuclei, Physical Review C 81, 034316 (2010).
56、P. W. Zhao, Z. P. Li, J. M. Yao, and J. Meng, New parametrization for the nuclear covariant energy density functional with a point-coupling interaction, Physical Review C 82, 054319 (2010).
57、Z. P. Li, T. Nikšić, D. Vretenar, P. Ring, and J. Meng, Relativistic energy density functionals: Low-energy collective states of 240Pu and 166Er, Physical Review C 81, 064321 (2010).
58、Z. P. Li, J. Meng, Y. Zhang, S. G. Zhou, and L. N. Savushkin, Single-particle Resonances in Deformed Dirac Equation, Physical Review C 81, 034311 (2010).
59、W. Zhang, Z. P. Li, S. Q. Zhang, and J. Meng, Octupole degree of freedom for the critical-point candidate nucleus 152Sm in a reflection-asymmetric relativistic mean-field approach, Physical Review C 81, 034302 (2010).
60、J. Meng, Z. P. Li, et al., Covariant Density Functional Theory for Nuclear Structure and Application in Astrophysics, Nuclear Physics A 834, 436c (2010).
61、Z. P. Li, Y. Zhang, D. Vretenar, and J. Meng, Single-Particle Resonances in a Deformed Relativistic Potential, Science China-physics mechanics & astronomy 53, 773 (2010).
62、W. Zhang, Z. P. Li, and S. Q. Zhang, Octupole deformation for Ba isotopes in a reflection-asymmetric relativistic mean-field approach, Chinese Physics C 34, 1094 (2010).
63、Z. P. Li, T. Nikšić, D. Vretenar, J. Meng, G. A. Lalazissis, and P. Ring, Microscopic analysis of nuclear quantum phase transitions in the N≈90 region, Physical Review C 79, 054301 (2009).
64、Z. P. Li, T. Nikšić, D. Vretenar, and J. Meng, Microscopic Analysis of Order Parameters in Nuclear Quantum Phase Transitions, Physical Review C 80, 061301(R) (2009).
65、T. Nikšić, Z. P. Li#, D. Vretenar, L. Prochniak, J. Meng, and P. Ring, Beyond the relativistic mean-field approximation. III. Collective Hamiltonian in five dimensions, Physical Review C 79, 034303 (2009).
66、Z. P. Li, T. Nikšić, D. Vretenar, J. Meng, G. A. Lalazissis, and P. Ring, Analysis of nuclear quantum phase transitions, AIP Conference Proceedings Volume 1165, pp. 219-220 (2009).
67、Z. P. Li, G. C. Hillhouse, and J. Meng, Energy-dependent Lorentz covariant parameterization of the NN interaction between 50 and 200 MeV, Physical Review C 77, 014001 (2008).
68、Z. P. Li, G. C. Hillhouse, and J. Meng, Validity of the relativistic impulse approximation for elastic proton-nucleus scattering at energies lower than 200 MeV, Physical Review C 78, 014603 (2008).
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Email :zpliphy@swu.edu.cn