当前位置:学院首页 >> 师资队伍>教授、研究员 >> 正 文

牛一斐

2021-05-18  核学院

 

姓    名: 牛一斐

职    称: 教  授

电子邮件: niuyf@lzu.edu.cn

办 公 室: beat365官方中文网页登录二分部现物楼208室

专    业: 粒子物理与原子核物理

研究方向: 原子核理论

课题组网址:nucl.lzu.edu.cn

教育经历

2007-2012   北京大学  物理学院  粒子物理与原子核物理   理学博士学位   导师: 孟杰 教授

2003-2007   北京大学  物理学院  理学学士学位

工作经历

2018.9---至今      beat365官方中文网页登录 beat365官方中文网页登录   教授、博导

2016.9---2018.9    欧盟极端光基础设施-核物理研究机构(ELI-NP)终身制研究员

2013.11--2016.5    意大利国家核物理实验室     博士后

2012.7---2013.11   中国工程物理研究院流体物理研究所 助理研究员

荣誉

中组部国家级人才计划青年项目

甘肃省领军人才

beat365官方中文网页登录“萃英学者”

beat365官方中文网页登录“巾帼标兵”

学术服务

国际核物理青年科学家暑期学校(NUSYS)组委会成员

国际核天体物理学校第16届NIC(Nuclei in Cosmos)学校地方组委会成员

上海光源SLEGS线站专家咨询委员会成员

主持科研项目

国家自然科学基金青年项目

国家自然科学基金面上项目

科技部高端外国专家引进计划项目

科技部国家重点研发计划青年科学家项目

研究方向

原子核理论:零温和有限温度密度泛函理论 多体格林函数理论 从头计算理论探索

原子核结构:原子核质量 原子核温度相变 原子核集体振动激发 原子核弱相互作用过程

核天体物理:宇宙重元素起源问题(快中子俘获过程)超新星爆发关键核物理问题  双中子星并合相关核物理问题 中子星性质

 

学术成果

发表学术论文60余篇,含《Phys. Rev. Lett.》2篇,《Phys. Lett. B》6篇和《Phys. Rev. C》27篇,受到《Rev. Mod. Phys.》《Phys. Rep.》、《Prog. Part. Nucl. Phys》等权威综述期刊文章的正面引用,得到国际理论和实验同行的广泛认可。受邀参与撰写科学出版社《中国学科发展战略·无中微子双B衰变实验》(2020年)和World Scientific出版社原子核物理国际评论系列丛书《Relativistic DensityFunctional forNuclearStructure》(2016年)以及《核物理国际评述》丛书第10卷《原子核结构的相对论密度泛函》的原子核集体振动模式章节。

主要论文列表如下:

(1)A. Ravlic, Y. F. Niu*, T. Niksic, N. Paar, and P. Ring, Finite-temperature linear response theory based on relativistic Hartree Bogoliubov model with point- coupling interaction, Phys. Rev. C 104, 064302 (2021).

(2)A. Ravlic*, E. Yuksel*, Y. F. Niu, and N. Paar*, Evolution of β-decay half-lives in stellar environments, Phys. Rev. C 104, 054318 (2021).

(3)A. Berceanu, Y. Xu, and Y. F. Niu*, Temperature e?ects on neutron-capture cross sections and rates through electric dipole transitions in hot nuclei,  Phys. Rev. C 104, 044332 (2021).

(4)W. L. Lv, Y. F. Niu*, and G. Colo,  Learning about the structure of giant resonances from their γ decay, Phys. Rev. C 103, 064321 (2021).

(5)D. Vale, Y. F. Niu, and N. Paar*, Nuclear charge-exchange excitations based on a relativistic density-dependent point-coupling model, Phys. Rev. C 103, 064307 (2021)

(6)Z. Z. Li, Y. F. Niu*, W. H. Long, Electric dipole polarizability in neutron-rich Sn isotopes as a probe of nuclear isovector properties, Phys. Rev. C 103, 064301 (2021).

(7)J. H. Bai, Z. M. Niu, B. Y. Sun, Y. F. Niu*, The description of giant dipole resonance key parameters with multitask neural networks, Phys. Lett. B 815, 136147 (2021).

(8)A. Ravlic, E. Yuksel, Y. F. Niu, G. Colo, E. Khan and N. Paar, Stellar electron-capture rates based on ?nite-temperature relativistic quasiparticle random-phase ap- proximation, Phys. Rev. C 102, 065804 (2020).

(9)Jia Liu, Yi Fei Niu, New magicity N = 32 and 34 due to strong couplings between Dirac inversion partners, Wen Hui Long, Phys. Lett. B 806, 135524 (2020).

(10)E. Yuksel, N. Paar, G. Colo, E. Khan and Y. F. Niu, Gamow-Teller excitations at ?nite temperature: Competition between pairing and temperature e?ects, Phys. Rev. C 101, 044305 (2020).

(11)Z. M. Niu*, J. Y. Fang and Y. F. Niu Comparative study of radial basis function and Bayesian neural network approaches in nuclear mass predictions , Phys. Rev. C 100, 054311 (2019).

(12)Z. M. Niu, H. Z. Liang*, B. H. Sun, W. H. Long, and Y. F. Niu , Predictions of nuclear beta-decay half-lives with machine learning and their impact on r-process nucleosynthesis , Phys. Rev. C 99, 064307 (2019).

(13)J. Geng, J. J. Li, W.H. Long*, Y. F. Niu, and S. Y. Yao, Pseudospin symmetry restoration and the in-medium balance between nuclear attractive and repulsive interactions, Phys. Rev. C 100, 051301 (2019).

(14)W. Zhang, and Y.F. Niu*, Critical temperature for shape transition in hot nuclei within covariant density functional theory, Phys. Rev. C 97, 054302 (2018).

(15)Y. F. Niu*, Z. M. Niu, G. Colo, and E. Vigezzi , Interplay of quasiparticle-vibration coupling and pairing correlations on β-decay half-lives, Phys. Lett. B 780, 325 (2018).

(16)Haozhao Liang*, Yifei Niu*, and Tetsuo Hatsuda* , Functional renormalization group and Kohn-Sham scheme in density functional theory, Phys. Lett. B 779, 436 (2018).

(17)W. Zhang, and Y. F. Niu*, Shape transition with temperature of the pear-shaped nuclei in covariant density functional theory, Phys. Rev. C 96, 054308 (2017).

(18)W. Zhang, and Y. F. Niu*, Shape evolution of 72,74Kr with temperature in covariant density functional theory, Chin. Phys. C 41, 094102 (2017).

(19)E. Yuksel*, G. Colo, E. Khan, Y. F. Niu, and K. Bozkurt, Multipole excitations in hot nuclei within the finite temperature quasiparticle random phase approximation framework, Phys. Rev. C 96, 024303 (2017).

(20)Z. M. Niu*, Y. F. Niu, H. Z. Liang*, W. H. Long, and J. Meng, Self-consistent relativistic quasiparticle random-phase approximation and its applications to charge- exchange excitations, Phys. Rev. C 95, 044301 (2017).

(21)Y. F. Niu*, G. Colo, E. Vigezzi, C. L. Bai, and H. Sagawa, Quasiparticle random-phase approximation with quasiparticle-vibration coupling: Application to the Gamow-Teller response of the superfluid nucleus 120Sn, Phys. Rev. C 94, 064328 (2016).

(22)Z. M. Niu*, B. H. Sun, H. Z. Liang, Y. F. Niu, and J. Y. Guo, Improved radial basis function approach with odd-even corrections, Phys. Rev. C 94, 054315 (2016).

(23)Z. Y. Wang, Y. F. Niu, Z. M. Niu*, and J. Y. Guo, Nuclear β-decay half-lives in the relativistic point-coupling model, J. Phys. G: Nucl. Part. Phys.43, 045108 (2016).

(24)Y. F. Niu*, Z. M. Niu, G. Colo, and E. Vigezzi, Particle-vibration coupling effect on the β-decay of magic nuclei, Phys. Rev. Lett. 114, 142501 (2015).

(25)Y. F. Niu*, G. Colo, and E. Vigezzi, Gamow-Teller response and its spreading mechanism in doubly magic nuclei, Phys. Rev. C 90, 054328 (2014).

(26)J. S. Zheng, N. Y. Wang, Z. Y. Wang, Z. M. Niu*, Y. F. Niu, and B. Sun, Mass predictions of the relativistic mean-field model with the radial basis function approach, Phys. Rev. C 90, 014303 (2014).

(27)Y. F. Niu, Z. M. Niu, N. Paar, D. Vretenar, G. H. Wang, J. S. Bai, and J. Meng*, Pairing transitions in finite-temperature relativistic Hartree-Bogoliubov theory, Phys. Rev. C 88, 034308 (2013).

(28)Z. M. Niu*, Z. L. Zhu, Y. F. Niu, B. H. Sun, T. H. Heng, and J. Y. Guo, Radial basis function approach in nuclear mass predictions, Phys. Rev. C 88, 024325 (2013).

(29)Z. M. Niu, Y. F. Niu, H. Z. Liang, W. H. Long, T. Niksic, D. Vretenar, and J. Meng*, β-decay half-lives of neutron-rich nuclei and matter flow in the r-process, Phys. Lett. B 273, 172 (2013).

(30)Z. M. Niu, Y. F. Niu, Q. Liu, H. Z. Liang*, and J. Y. Guo, Nuclear β+/EC decays in covariant density functional theory and the impact of isoscalar proton- neutron pairing, Phys. Rev. C 87, 051303 (2013).

(31)D. Vretenar*, Y. F. Niu, N. Paar, and J. Meng, Low-energy isovector and isoscalar dipole response in neutron-rich nuclei, Phys. Rev. C 85, 044317 (2012).

(32)Y. F. Niu*, G. Colo, M. Brenna, P. F. Bortignon, and J. Meng, Gamow-Teller response within Skyrme random-phase approximation plus particle-vibration coupling, Phys. Rev. C 85, 034314 (2012).

(33)Y. F. Niu, N. Paar, D. Vretenar, and J. Meng*, Stellar electron-capture rates calculated with the finite-temperature relativistic random-phase approximation, Phys. Rev. C 83, 045807 (2011).

(34)Y. F. Niu, N. Paar*, D. Vretenar, and J. Meng, Low-energy monopole and dipole response in nuclei at finite temperature, Phys. Lett. B 681, 315 (2009).

(35)N. Paar*, Y. F. Niu, D. Vretenar, and J. Meng, Isoscalar and isovector splitting of pygmy dipole structure, Phys. Rev. Lett. 103, 032502 (2009).

 

近五年邀请报告

2021.10.  Technical Meeting on Arti?cial Intelligence for Nuclear Technology and Applications  Online, 2021.10.25. - 10.29.  

2021.9.     原子核第一性原理计算与弱相互作用过程研讨会  Chongqing, China 2021.9.23. - 9.26.

2021.7.     原子核中的电磁性质理论研讨会 Changchun, China 2021.7.16. - 7.17.

2021.5.     无中微子双贝塔衰变研讨会 Zhuhai, China 2021.5.19. - 5.23.

2020.12.   SLEGS-2020 光核物理研究及伽马源应用研讨会 Shanghai, China 2020.12.7. - 12.8.

2019.12.   First workshop on NνDEx Lanzhou, China 2019.12.14. - 12.15.

2019.10.   第4届西北地区理论物理前沿学术研讨会 Yinchuan, China 2019.10.18. - 10.21.

2019.10.   第17届全国核物理大会 Wuhan, China 2019.10.8. - 10.12.

2019.1.   RIBLL合作组第14次会议 Zhuhai, China 2019.1.4. - 1.7.

2018.11.   无中微子双贝塔衰变机制和核矩阵元计算研讨会  Lanzhou, China 2018.11.16. - 11.19.

2018.10.   Workshop on Neutrinoless Double Beta Decays and Other Science Frontiers of Low Background in Underground Labs Shanghai, China 2018.10.15. - 10.16.

2018.6.   International conference on nuclear structure and related topics Burgas, Bulgaria 2018.6.3. - 6.9.

2018.5.    Workshop on   "Recent Developments in Nuclear and Hadron Physics Hefei, China 2018.5.26. - 5.29.

2018.5.   Chengdu-CUSTIPEN workshop on theory of rare nuclear decays Chengdu, China 2018.5.13. - 5.18.

2017.9.   XXIV Nuclear Physics Workshop “Marie & Pierre Curie” Kazimierz Dolny, Poland 2017.9.20. - 9.24.

2017.9.   Advanced many-body and statistical methods in mesoscopic systems Busteni, Romania 2017.9.4. - 9.8.

2017.6.   China-Japan collaboration workshop on ”Nuclear mass and life for unravelling mysteries of r-process, Ksukuba, Japan 2017.6.26. - 6.28.

2017.6.   Interdisciplinary Symposium on Modern Density Functional Theory Wako, Japan 2017.6.19. - 6.23.

2017.5.   The 12th International Spring Seminar on Nuclear Physics“Current Problems and Prospects for Nuclear Structure” Ischia, Italy 2017.5.15 - 5.19.

2017.3.   Workshop Spin-Isopin excitations and related nuclear structure problems Milan, Italy 2017.3.13. - 3.14.

该网页更新日期:2022.3.

欢迎校内外对理论核物理感兴趣的本科生和研究生加入我们!

课题组网站地址:nucl.lzu.edu.cn

上一篇:龙文辉

下一篇:潘多强(青年教授)