个人信息
Personal information
教授
博士生导师
硕士生导师
性别:女
入职时间:2017-10-09
在职信息:在职
所在单位:技术物理系
学历:研究生(博士后)
学位:博士学位
学科:粒子物理与原子核物理
毕业院校:北京大学
办公地点:加速器楼215
电子邮箱:
联系方式:010-62753560
曾获荣誉:2024年科学探索奖
2023年教育部“长江学者奖励计划”特聘教授
2023年北京大学实验核物理团队荣获北京串列加速器核物理国家实验室35周年杰出贡献团队
2022年文章入选第七届中国科协优秀科技论文
2022年第十七届中国青年女科学家奖
2021年课题组入选北京串列加速器核物理国家实验室年度优秀用户
2021年北京大学黄廷方/信和青年杰出学者奖
2020和2022年北京大学核物理与核技术国家重点实验室“优秀成果奖”
2019年国家级重大人才青年计划(海外人才引进青年项目)
2019年国际纯粹与应用物理联合会IUPAP青年科学家奖
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近五年国内外学术会议报告
(Invited Plenary Speaker) “New opportunities of laser spectroscopy on exotic nuclei”, National nuclear physics conference 2023(第十八届全国核物理大会), Huzhou, Zhejiang, China, 12-16 May 2023
(Invited)“Shape coexistence investigated by high-resolution laser spectroscopy” Workshop on Shape Coexistence, E0 Transitions, and Related Topics, Geulph, Canada, 1-5May, 2023 (online)
(Invited)“Discussion of the opportunities for laser spectroscopy studies of exotic nuclei at HIAF RIB facility”, Symposium on the Frontier Research of Nuclear Structure and Reaction based at RIB facilities (基于大科学装置的核结构和核反应基础前沿问题研讨会), Huizhou, Guangdong, China, 4-5th May, 2023
(Invited)“The opportunities to study the hyperfine structure of the atoms or molecule containing unstable heavy nuclei”Symposium on unstable and superheavy nuclei(不稳定核和超重核研究学术研讨会), Nanjing, Jiangsu, China, 9-12nd April 2023
(Oral) “Development of the collinear laser spectroscopy system for the study of unstable nuclei at BRIF facility” EMIS 2022,RISP/IBS, Daejeon, Korea, October 3-7, 2022
(Invited) “基于精密激光核谱技术的不稳定核奇特结构研究” Symposium on Nuclear Physics Frontiers and Intersections(SYNPFI),8月25日-8月28日, 2022 北京,香山饭店
(Invited) “核外电子与原子核的交叉作用会带来什么” 新一代奇异核素工厂与奇异核素性质研究暑期学校 – 河南新乡,7月15日-8月04日, 2020 (线上)
(Invited) 3rd International Conference on Hyperfine Interactions and their Applications – HYPERFINE2021, 5-10th, Sep, 2021 (罗马尼亚)
(Invited Plenary Speaker ) “丰中子新幻数的最新研究及激光核谱实验室建设进展” (2021年度全国核反应大会) National Nuclear reaction conference, 15-21th June,2021
(Invited) “Exotic nuclear structure studies of neutron-rich nuclei at PKU” NSFC/JSPS/NRF A3 Foresight Nuclear Physics in the 21st Century Program “Nuclear Physics in the 21st Century ” 2020 Annual Meeting, HuiZhou,China, 18-19 November, 2020
(Invited) “Laser spectroscopy at BRIF” BRIF User Meeting, Beijing, China, 10th December, 2019
(Invited) “Nuclear structure studies in the Ca/Ni region using laser spectroscopy” JSPS/NRF/NSFC A3 Foresight Program “Nuclear Physics in the 21st Century” Joint Kickoff Meeting, Kobe, Japan, 6-7th December, 2019
(Invited )“Probing the exotic nuclear structure via high-resolution laser spectroscopy”WLA 2nd Annual Forum(第二届世界顶尖科学家论坛), Shanghai, China, 29th Otc -1st Nov., 2019
(Invited Plenary Speaker) “Nuclear structure of unstable nuclei studied by using precision laser spectroscopy” National nuclear physics conference 2019(第十七届全国核物理大会), Wuhan, China, 09-12 October, 2019
(Invited Plenary speaker) “High-Resolution Laser Spectroscopy for the Study of Exotic Nuclear Properties” INPC 2019, Scottish Event Campus, Glasgow,UK, 29 July-2 August, 2019
(Invited ) “Precision Laser Spectroscopy”基于华南大科学装置集群的核物理前沿暑期讲习班 (Summer School) Zhuhai, China, 15 July,2019
(Invited) “Nuclear properties of neutron rich isotopes in Ca region” Many body system with strong interaction workshop, Lanzhou, China, 10-15 June, 2019
(Invited) “Laser spectroscopy techniques: For the nuclear properties of exotic isotopes” Workshop on Physics at HAIF High-Energy Beam lines, Beihang Uni. Beijing, China, December13-15,2018
(Invited) “Nuclear moments of exotic isotope in the Ni region” gSPEC workshop, Milan, Italy, September 27-28th, 2018
(Invited) “Nuclear structure studies by using the nuclear properties” 20th Northeastern Asian Symposium on Nuclear Physics in the 21st Century, Nagoya, Japan, September 18-21,2018
(Invited)“Laser spectroscopy techniques for the study of radioactive isotopes”. Sino-German-Workshop, Lanzhou, China, August13-15th, 2018
(Invited)“Nuclear moment studies using collinear laser spectroscopy”, Nuclear Structure 2018, East Lansing, MI, USA, August 5-10, 2018
(Plenary speaker) “Investigating nuclear structure of exotic isotopes by laser spectroscopy” National Nuclear Structure conference (全国核结构大会) 2018, Dalian, China, July, 2018
(Invited)“Nuclear charge radii probed by laser spectroscopy”, Workshop “QED and QCD Effects in Atomic and Hadron Physics”, CAS, Lanzhou, China, 31st Jan-5th Feb 2018
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发表论文列表
第一作者/通讯作者文章
22. Control and data acquisition system for collinear laser spectroscopy experiments;P. Zhang, H.R. Hu, X.F. Yang* et al.,Nucl. Instr. and Meth. in Phys. Res. B 541, 37(2023)
21. Control and data acquisition system for collinear laser spectroscopy experiments;Y.C. Liu, X.F. Yang* et al.,Nuclear Science and Techniques 34, 38 (2023)
20. 用于不稳定原子核研究的共线激光谱仪研制进展;张鹏,刘寅绅,白世伟*,杨晓菲* 科学通报 68, 1054 (2023)
19. Laser Spectroscopy for the study of exotic nuclei. X. F. Yang*, S. J. Wang, S.G. Wilkins*, R.F. Garcia Ruiz* et al., Progress in Particle and Nuclear Physics, 129,104005(2023)
18. Electromagnetic moments of scandium isotopes and N = 28 isotones in the distinctive 0f7/2 orbit. S.W. Bai, A. Koszorus, B.S. Hu, X. F. Yang* et al., Physics Letters B, 829, 137064 (2022)
17. Construction and commissioning of the collinear laser spectroscopy system at BRIF. S.J. Wang, X. F. Yang* et al., Nucl. Instr. and Meth. in Phys. Res. A 1032,166622 (2022).
16. Commissioning of a high-resolution collinear laser spectroscopy apparatus using a laser ablation ion sources. S.W. Bai, X. F. Yang* et al., Nuclear Science and Techniques, 33,9 (2022)[封面文章]
15. Charge radii of exotic potassium isotopes challenge nuclear theory and the magic character of N=32; A. Koszorus*, X.F. Yang* et al., Nature Physics 17, 439 (2021)
(Highlight at “News and Views” of Nature Physics)
14. Nuclear moments of germanium isotopes near N=40, A. Kanellakopoulos, X.F. Yang* et al., Physical Review C 102, 054331 (2020).
13. 丰中子Zn核素奇特核结构讨论和展望; 王姝婧,白世伟,杨晓菲* 原子核物理评论37,1-10 (2020)
12. Precision measurement of the charge radii of potassium isotopes; A. Koszorus, X.F. Yang* et al., Physical Review C 100,034304 (2019)
11. Nuclear charge radii of 62-80Zn and their sensitivity to cross-shell proton excitations; L. Xie, X.F.Yang* et al., Physics Letters B 797, 134805 (2019)
10. 用于核物理研究的精密激光谱技术的发展和展望; 刘永超,白世伟,杨晓菲*, 原子核物理评论 36, 161 (2019)
09. 基于不稳定核基本性质测量的原子核结构研究; 白世伟, 杨晓菲 原子核物理评论 35, 382 (2019)
08. Precision Laser Spectroscopy Technique for Exotic Radioactive Beams at CERN-ISOLDE; X.F.Yang*, Journal of Physics: Conference Series 1024, 012031 (2018)
07. Investigating the abnormal deformation of the 5/2+ isomeric state in 73Zn:indicator for triaxiality; X.F.Yang* et al., Physical Review C 97, 044324 (2018)
06. Evolution of nuclear structure in neutron-rich odd-Zn isotopes and isomers; C. Wraith, X.F. Yang* et al., Physics letters B 771, 385 (2017).
05. Isomer shift and magnetic moment of the long-lived 1/2+ isomer in 79Zn49: signature of shape coexistence near 78Ni; X.F. Yang* et al., Physical Review letters 116, 182502 (2016)
(Highlighted as Editor’s suggestion)
04. Laser-RF double resonance spectroscopy of 84-87Rb isotopes trapped in superfluid helium; X.F. Yang* et al., Physical Review A 90, 052516 (2014)
03. Control of stopping position of radioactive ion beam in superfluid helium for laser spectroscopy experiments; X.F. Yang* et al., Nucl. Instr. and Meth. in Phys. Res. B 317, 599 (2013)
02. Precision measurement of laser RF double resonance spectra with an effective compensation of residual magnetic field; X. F. Yang* et al., Hyperfine Interactions 227, 147 (2014)
01. An effective method for precisely trapping ion beams in superfluid helium for laser spectroscopy experiments. X.F. Yang* et al., EPJ Web of Conferences 66, 11041 (2014)
合作者文章列表
2022
74. Isotope shift factors for Cd+ 5s 2S1/2-5p 2P3/2 transition and determination of Cd nuclear charge radii; J.Z. Han, C. Pan, K.Y Zhang, X.F. Yang et al., Phys. Rev. Research 4, 033049 (2022)
74. Nuclear moments of indium isotopes reveal abrupt change at magic number 82; A.Vernon et al., Nature 607, 260-265 (2022)
73. Investigation of negative-parity states in 16C via deuteron inelastic scattering; Z.W. Tan et al., Chinese Physics C , 46, 054002 (2022)
72.Observation of the-pi-sigma bond linear-chain molecular structure in 16C; J.X. Han, Y. Liu, Y.L.Ye, X.F. Yang et al., Phys. Rev. C 105, 044302 (2022)
71.New investigation of low-lying states in 12Be via a 2H(13B,3He) reaction;W. Liu et al., Phys. Rev. C 105, 034613 (2022)
70. Isotope shift factors for the Cd+ transition and determination of Cd nuclear charge radii; J.Z. Han et al., Physical Review Research , 4, 033049 (2022)
69. Nuclear Charge Radii of the Nickel Isotopes; S Malbrunot-Ettenauer et al., Phys. Rev. Lett. 128, 022502 (2022)
2021
68. s- and d-wave intruder strengths in 13B g.s. via the 1H(13B,d)13B reactions; W. Liu et al., Physical Review C, 104, 064605 (2021)
67. Performance of the CAT-TPC based on two-dimensional readout strips; L. S. Yang et al., Nuclear Science and Techniques, 32, 85 (2021)
66. Isotope Shifts of Radium Monofluoride Molecules; S. M. Udrescu et al., Phys. Rev. Lett. 127, 33001 (2021)
(Highlighted as Editors' Suggestion and Viewpoint: Sizing up Exotic Nuclei with Radioactive Molecules)
65. Property investigation of the wedge-shaped CsI(TI) crystals for a charged-particle telescope; G. Li et al., Nuclear Inst. and Methods in Physics Research A, 1013 165637 (2021)
64. Probing the single-particle behavior above 132Sn via electromagnetic moments of 133,134Sb and N = 82 isotones; S. Lechner et al., Phys. Rev. C 104, 014302 (2021)
63. Novel evidence for the sigma-bond liner-chain molecular structure in 14C; H. Z. Yu et al., Chinese. Phys. C 45, 084002 (2021)
62. Observation of the near-threshold intruder 0- resonance in 12Be; J. Chen et al., Phys. Rev. C 103, L031302 (2021)
61. High-resolution laser spectroscopy of 27-32Al; H. Heylen et al., Phys. Rev. C 103, 014318 (2021)
2020
60. 与HIAF装置相关的放射性核束物理研究;叶沿林,杨晓菲等., 中国科学:物理学力学天文学,50,112003(2002)
59. Eikonal method for charge-exchange reactions at intermediate energies; J.J. Li et al., Phys. Rev. C 102, 064601 (2020)
58. Doubly-magic character of 132Sn studied via electromagnetic moments of 133Sn; L.V. Rodriguez et al., Phys. Rev. C 102, 051301(R) (2020)
57. Tin resonance-ionization schemes for atomic- and nuclear structure studies; F. P. Gustafsson et al., Phys. Rev. A 102, 052812 (2020)
56. Spallation and fragmentation cross sections for 168 MeV/nucleon 136Xe ions on proton, deuteron and carbon targets; Sun et al., Phys. Rev. C 101, 064623 (2020)
55.Laser spectroscopy of indium Rydberg atom bunches by electric field ionization;A. R.Vernon et al., Scientific Reports 10, 12306 (2020).
54. Positive-parity linear-chain molecular band in 16C; Y.Liu et al., Physical Review Letters 124,192501(2020)
53. Structural trends in atomic nuclei from laser spectroscopy of tin; Deyan Yordanov et al., Communication Physics 3, 107 (2020)
52. Charge radius of the short-lived 68Ni and correlation with the dipole polarizability; S. Kaufmann et al., Physical Review Letters 124, 132502 (2020)
51. g-factor of the 99Zr isomer: monopole evolution in the shape-coexisteting region; F. Boulay et al., Physical Review Letters 124, 112501 (2020)
50. Measurement and microscopic description of charge radii of odd-even staggering of charge radii of exotic copper isotopes. R. P. de Groote et al.,Nature Physics 16, 620 (2020)
49. Spectroscopy of short-lived radioactive molecules, Ronald Fernando Garcia Ruiz et al., Nature 581,396-400(2020)
48. Determination of the cluster-decay branching ratio from a near-threshold molecular state in 10Be; W. Jiang et al., Phys. Rev. C 101, 031304(R) (2020)
47. Quadrupole deformation of 16C studied by proton and deuteron inelastic scattering; Y. Jiang, et al., Physical Review C 101,024601(2020)
46. Analytic Response Relativistic Coupled-Cluster Theory: The first application to indium isotope shifts, B.K Sahoo et al., New Journal of Physics (2020)
45. A compact linear Paul trap cooler buncher for CRIS; C.M Ricketts et al., Nuclear Inst. and Methods in Physics Research B 463,375 (2020)
44. Optimising the Collinear Resonance Ionisation Spectroscopy (CRIS) experiment at CERN-ISOLDE; A.R.Vernon et al., Nuclear Inst. and Methods in Physics Research B 463,384 (2020)
43. Resonance ionization schemes for high resolution and high efficiency studies of exotic nuclei at the CRIS experiment; Á. Koszorús et al., Nuclear Inst. and Methods in Physics Research B 463,
398(2020)
2019
42. Improved eikonal approach for charge exchange reactions at intermediate energies, J. J. Li et al., Chinese Physics C 43, 124102 (2019)
41. Spin determination by in-plane angular correlation analysis in various coordinate systems, B. Yang, Y. L. Ye,* et al., Chinese Physics C 43, 084001 (2019)
40. Investigation of the 14C+α molecular configuration in 18O by means of transfer and sequential decay reaction. B. Yang, Y. L. Ye,*, J. Feng et al., Physical Review C 99, 064315 (2019)
39. A compact RFQ cooler buncher for CRIS experiments; B.S Cooper et al., Hyperfine Interactions 240, 52 (2019)
38. Laser Spectroscopy of Neutron-Rich Tin Isotopes: A Discontinuity in Charge Radii across the Shell Closure; C Gorges et al., Physical review letters 122, 192502 (2019)
(Highlighted as Editors' Suggestion and Viewpoint: Tin Gets Kinky)
37. Negative Parity States in 39Cl Configured by Crossing Major Shell Orbits; L.C. Tao et al., Chinese Physics Letters 36, 062101(2019)
36. A new beamline for laser spin-polarization at ISOLDE; W. Gins et al., Nuclear Inst. and Methods in Physics Research A 925, 24 (2019)
35. Simulation of the relative atomic populations of elements 1 ≤ Z ≤89 following charge exchange tested with collinear resonance ionization spectroscopy of indium; A.R.Vernon et al., Spectrochimica Acta
Part B: Atomic Spectroscopy 153, 61 (2018)
34. Interplay between nuclear shell evolution and shape deformation revealed by the magnetic moment of 75Cu; Y. Ichikawa et al., Nature Physics 15,321 (2019)
33. Enhanced monopole transition strength from the cluster decay of 13C; Jun Feng, YanLin Ye*, et al., Science China Physics, Mechanics & Astronomy 62 , 12011(2019)
2018
32. Multi-photon ionization of accelerated laser-ablated ions: exploring physics over a wide range of energy scales; R.F. Garcia Ruiz et al., Physical Review X 8,041005(2018)
(Highlighted as Viewpoint: Resonant Ionization Spectroscopy Technique Becomes Tabletop Friendly)
31. Study of the low-lying states in 12Be using one-neutron transfer reaction; J. Chen et al., Physical Review C 98, 014616 (2018)
30. Investigation of the near-threshold cluster resonance in 14C; Hong-Liang Zang, Yan-Lin Ye* et al., Chinese Physics C 42, 074003 (2018)
29. Investigation of the thickness non-uniformity of the very thin silicon-strip detectors; Qiang Liu, Yanlin Ye*, et al., Nuclear Inst. and Methods in Physics Research A 897,100 (2018) ;
28. A new measurement of the intruder configuration in 12Be; J. Chen et al., Physics Letters B 781, 412 (2018)
27. Nuclear moments of the low-lying isomeric 1+ state of 34Al: Investigation on the neutron 1p1h excitation across N = 20 in the island of inversion;Z.Y. Xu et al., Physics Letters B 782, 619 (2018)
26. Proton single particle energies next to 78 Ni: Spectroscopy of 77 Cu via single proton knock-out reaction; Zs. Vajta et al., Physics Letters B 782, 99 (2018)
25. The nuclear magnetic moment of 208Bi and its relevance for a test of bound-state strong-field QED;S. Schmidt et al., Physics Letters B 779, 324 (2018)
24. Laser-spectroscopy studies of the nuclear structure of neutron-rich radium; K. M. Lynch et al., Physical Review C 97, 024309 (2018)
23. Radium ionization scheme development: The first observed autoionizing states and optical pumping effects in the hot cavity environment; T. D. Goodacre et al., Spectrochimica Acta Part B: Atomic
Spectroscopy 150, 99 (2018)
2017
22. Probing the 31Ga ground-state properties near the Z=28 region with high-resolution laser spectroscopy; G.J.Farooq-Smith et al., Physical Review C 96, 044324 (2017)
21. Dipole and quadrupole moments of 73-78Cu as a test of the robustness of the Z=28 shell closure near 78Ni; R.P. de Groote et al., Physical Review C 96, 041302(R) (2017)
20. Quadrupole moment of 203Fr; S.G.Wilkins et al., Physics Review C 96, 034317(2017)
19. Development of a sensitive setup for laser spectroscopy studies of very exotic calcium isotopes; R.F.Garcia Ruiz et al., Journal of Physics G: Nuclear and Particle Physics 44, 044003 (2017)
18. New laser polarization line at the ISOLDE facility; M Kowalska et al., Journal of Physics G: Nuclear and Particle Physics 44, 084005(2017)
2016
17. Changes in nuclear structure along the Mn isotopic chain studied via charge radii; H Heylen, et al, Physical Review C 94, 054321(2016)
16. Laser and decay spectroscopy of the short-lived isotope Fr 214 in the vicinity of the N= 126 shell closure; Gregory James Farooq-Smith et al., Physical Review C 94, 054305(2016)
15. Quadrupole Moments of odd-A 53-63Mn: Strong Onset of Collectivity towards N = 40. C. Babcock et al ., Physics Letters B 760, 387 (2016)
14. Investigating nuclear shell structure in the vicinity of 78Ni: Low-lying excited states in the neutron-rich isotopes 80,82Zn. Y. Shiga et al., Physical Review C 93, 024320 (2016)
13. Combined high-resolution laser spectroscopy and nuclear decay spectroscopy for the study of the low-lying states in 206Fr, 202At, and 198Bi. K.M. Lynch et al., Physical Review C 93, 014319 (2016)
12. High-resolution laser spectroscopy with the Collinear Resonance Ionization Spectroscopy (CRIS) experiment at CERN-ISOLDE. T.E. Cocolios et al., Nucl. Instr. and Meth. in Phys. Res. B 376,
284(2016)
2015
11. Use of a Continuous Wave Laser and Pockels Cell for Sensitive High-Resolution Collinear Resonance Ionization Spectroscopy. R.P. de Groote et al., Physical Review Letters 115, 132501 (2015)
10. Measurement of the hyperfine splitting of alkali atoms in superfluid helium for laser spectroscopy of atoms with unstable nuclei. K. Imamura et al., JPS Conf. Proc.6 , 030115 (2015)
09. Production of Spin Polarized 58Cu and its Magnetic Moment. M. Mihara et al., JPS Conf. Proc. 6, 030114 (2015)
08. Persistence of N = 50 Shell Closure in the Vicinity of 78Ni Studied by In-Beam Gamma Ray Spectroscopy. Y. Shiga et al., JPS Conf. Proc. 6, 030008 (2015)
07. Measurement of hyperfine structure of Au atom in superfluid helium. T. Fujita et al., JPS Conf. Proc. 6, 030116 (2015)
06. Laser spectroscopy of atoms in superfluid helium for the measurement of nuclear spins and electromagnetic moments of radioactive atoms. T. Fujita et al., Hyperfine Interact 236 95 (2015)
05. Measurement of the hyperfine splitting of 133Cs atoms in superfluid helium. K. Imamura et al., Hyperfine Interact 230, 73 (2015)
04. Development of a helium cryostat for laser spectroscopy of atoms with unstable nuclei in superfluid helium. K. Imamura et al., Nucl. Instr. and Meth. in Phys. Res. B 317, 595 (2013)
03. Development of an adiabatic field rotation system to measure spin polarization of unstable nuclei. Y.Ishibashi et al., Nucl. Instr. and Meth. in Phys. Res. B 317, 714 (2013)
02. Development of a new device control system for beta-NMR experiments. N.Yoshida et al., Nucl. Instr. and Meth. in Phys. Res. B 317 705 (2013)
01. Novel nuclear laser spectroscopy method using superfluid helium for measurement of spins and moments of exotic nuclei. T. Furukawa, T. Wakui, X.F. Yang et al., Nucl. Instr. and Meth. in Phys. Res.
B 317,590 (2013)