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

doi:10.11804/NuclPhysRev.36.02.161

留言板

尊敬的读者、作者、审稿人, 关于本刊的投稿、审稿、编辑和出版的任何问题, 您可以本页添加留言。我们将尽快给您答复。谢谢您的支持!

姓名
邮箱
手机号码
标题
留言内容
验证码

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

文章导航 > 原子核物理评论 > 2019 > 36(2): 161-169

刘永超, 白世伟, 杨晓菲. 用于核物理研究的精密激光谱技术的发展和展望[J]. 原子核物理评论, 2019, 36(2): 161-169. doi: 10.11804/NuclPhysRev.36.02.161

引用本文:

刘永超, 白世伟, 杨晓菲. 用于核物理研究的精密激光谱技术的发展和展望[J]. 原子核物理评论, 2019, 36(2): 161-169. doi: 10.11804/NuclPhysRev.36.02.161

LIU Yongchao, BAI Shiwei, YANG Xiaofei. Development and Prospect of Precision Laser Spectroscopy Techniques for Nuclear Physics Study[J]. Nuclear Physics Review, 2019, 36(2): 161-169. doi: 10.11804/NuclPhysRev.36.02.161

Citation:

LIU Yongchao, BAI Shiwei, YANG Xiaofei. Development and Prospect of Precision Laser Spectroscopy Techniques for Nuclear Physics Study[J]. Nuclear Physics Review, 2019, 36(2): 161-169. doi: 10.11804/NuclPhysRev.36.02.161

用于核物理研究的精密激光谱技术的发展和展望

doi: 10.11804/NuclPhysRev.36.02.161

1.
北京大学物理学院和核物理与核技术国家重点实验室, 北京 100871;
2.
兰州大学核科学与技术学院, 兰州 730000

基金项目: 国家重点研发计划项目（2018YFA0404403）；国家自然科学基金面上项目（11875073）

详细信息

作者简介:
刘永超(1997-),男,山东青岛人,准博士研究生,从事粒子物理与原子核物理研究;E-mail:ychliu2015@lzu.edu.cn

通讯作者: 杨晓菲,E-mail:xiaofei.yang@pku.edu.cn

中图分类号: O571.3

Development and Prospect of Precision Laser Spectroscopy Techniques for Nuclear Physics Study

1.
School of Physics and State Key Laboratory of Nuclear Physics and Technology, Peking University, Beijing 100871, China;
2.
School of Nuclear Science and Technology, Lanzhou University, Lanzhou 730000, China

Funds: National Key R&D Program of China (2018YFA0404403); National Natural Science Foundation of China (11875073)

摘要: 原子核基本性质（自旋、质量、寿命、磁矩、电四极矩和电荷半径等）与原子核的内在结构密切相关，是检验和发展原子核理论模型的重要依据。实验上可以通过多学科交叉的精密激光谱技术测量原子核外电子的超精细结构和同位素移位，来模型独立地提取原子核的自旋、磁矩、电四极矩和电荷均方根半径等多个核物理参量。这些基本性质的系统测量可以用于探索不稳定原子核中展现出来的新奇的物理现象与规律。近年来，为了测量产额更低的丰中子核的基本性质，激光谱技术不断更新和发展，以实现高分辨、高效率测量。本文详细介绍了激光谱测量的基本原理以及由此发展起来的用于不稳定原子核结构研究的各类互补的激光谱学技术，如共线激光谱（高分辨率低灵敏度）、在源激光谱（高灵敏度低分辨率）、共线共振电离谱（高分辨率高灵敏度）等激光谱技术，以及在不同核区的测量优势和局限。最后结合我国正在发展和规划中的新一代放射性核束装置，讨论精密激光谱技术在国内的发展以及在核物理研究中的应用。
- 放射性核素 /
- 核基本性质 /
- 激光谱技术 /
- 高分辨高效率 /
- 核结构
Abstract: The nuclear properties (spin, mass, life-time, magnetic moment, electric quadrupole moment and charge radius) of the ground and long-lived states of unstable nuclei can be used to explore the exotic nuclear structure phenomenon, and also will be a prominent input for the nuclear theory methods and nuclear interactions. Experimentally, we can nuclear-model independently determine the nuclear spins, magnetic moments, electric quadrupole moments and mean square charge radii simultaneously from hyperfine structure and isotope shift, measured with the interdisciplinary laser spectroscopy techniques. In recent years, with the continuous efforts, various laser spectroscopy techniques with high resolution and high efficiency have been developed in order to study the short-lived isotopes produced at the radioactive ion beam facilities with very low production yield. Here, we will introduce the basic principle of laser spectroscopy measurement and discuss in detail the various complementary laser spectroscopy techniques developed for the nuclear structure study of unstable isotopes. The advantages and disadvantages of these techniques, such as collinear laser spectroscopy (high resolution, low sensitivity), in-source laser spectroscopy (high sensitivity, low resolution), as well as collinear resonant ionization (high resolution, high sensitivity), are discussed regarding to the resolution and sensitivity, which is highly related to the application of the technique in different mass region of nuclear chart. In addition, future plan and prospect on the development of the precision laser spectroscopy techniques will be discussed, which, with the hope, will be used for nuclear physics study at the next-generation facilities constructed and planed in China.
- radioactive isotop /
- nuclear properties /
- laser spectroscopy technique /
- high resolution and high efficiency /
- nuclear structure

[1]	NEYENS G. Rep Prog Phys, 2003, 66:633.
[2]	TANIHATA I, KOBAYASHI T, YAMAKAWA O, et al. Phys Lett B, 1988, 206:592.
[3]	FRICKE G, HEILIG K. Nuclear Charge Radii[M]. Heidelberg:Springer-Verlag, 2004:385.
[4]	YANG X F, COLLAPS and CRIS collaboration. J Phys Conf Ser, 2018, 1024:012031.
[5]	FRANBERG H, DELAHAYE P, BILLOWES J, et al. Nucl Instr and Meth B, 2008, 266:4502.
[6]	PAPUGA J, BISSELL M L, KREIM K, et al. Phys Rev Lett, 2013, 110:172503.
[7]	LU Z T, MUELLER P, DRAKE G W F, et al. Rev Mod Phys, 2013, 85:1383.
[8]	GARCIA RUIZ R F, BISSELL M L, BLAUM K, et al. Phys Rev C, 2015, 91:041304.
[9]	YANG X F, Wraith C, Xie L, et al. Phys Rev Lett, 2016, 116:182502.
[10]	BAI S W, YANG X F. Nuclear Physics Review, 2018, 35:382. (in Chinese) (白世伟, 杨晓菲. 原子核物理评论, 2018, 35:382.)
[11]	DE GROOTE R P, BILLOWES J, BINNERSLEY C L, et al. Phys Rev C, 2017, 96:041302.
[12]	NEUGART R, BILLOWES J, BISSELL M L, et al. J Phys G:Nucl Part Phys, 2017, 44:064002.
[13]	DICKER A R, CAMPBELL P, CHEAL B, et al. Hyperfine Interact, 2014, 227:139.
[14]	MINAMISONO K, MANTICA P F, KLOSE A, et al. Nucl Instr and Meth A, 2013, 709:85.
[15]	VOSS A, PROCTER T J, SHELBAYA O, et al. Nucl Instr and Meth A, 2016, 811:57.
[16]	FEDOSSEEV V, CHRYSALIDIS K, DAY GOODACRE T, et al. J Phys G:Nucl Part Phys, 2017, 44:084006.
[17]	FEDOSSEEV V N, KUDRYAVTSEV YU, MISHIN V I. Phys Scr, 2012, 85:058104.
[18]	FEDOSSEEV V N, FEDOROV D V, HORN R, et al. Nucl Instr and Meth B, 2003, 204:353.
[19]	COCOLIOS T E. Hyperfine Interact, 2017, 238:16.
[20]	MARSH B A, DAY GOODACRE T, SELS S, et al. Nat Phys, 2018, 14:1163.
[21]	COCOLIOS T E, ANDREYEV A N, BASTIN B, et al. Phys Rev Lett, 2009, 103:102501.
[22]	FERRER R, BREE N, COCOLIOS T E, et al. Phys lett B, 2014, 728:191.
[23]	HIRAYAMA Y, MUKAI M, WATANABE Y X, et al. Phys Rev C, 2017, 96:014307.
[24]	BACKE H, EBERHARDT K, FELDMANN R, et al. Nucl Instr and Meth B, 1997, 126:406.
[25]	FERRER R, BARZAKH A, BASTIN B, et al. Nat Commun, 2017, 8:14520.
[26]	ZADVORNAYA A, CREEMERS P, DOCKX K, et al. Phys Rev X, 2018, 8:041008.
[27]	SANCHEZ R, NORTERSHAUSER W, EWALD G, et al. Phys Rev Lett, 2006, 96:033002.
[28]	NORTERSHAUSER W, TIEDEMANN D, ZAKOVA M, et al. Phys Rev Lett, 2009, 102:062503.
[29]	FLANAGAN K T, VINGERHOETS P, AVOGULEA M, et al. Phys Rev Lett, 2009, 103:142501.
[30]	GARCIA RUIZ R F, BISSELL M L, BLAUM K, et al. Nat Phys, 2016, 12:594.
[31]	WRAITH C, YANG X F, XIE L, et al. Phys Lett B, 2017, 771:385.
[32]	YANG X F, TSUNODA Y, BABCOCK C, et al. Phys Rev C, 2018, 97:044324.
[33]	NEYENS G, KOWALSKA M, YORDANOV D, et al. Phys Rev Lett, 2005, 94:022501.
[34]	YORDANOV D T, BISSELL M L, BLAUM K, et al. Phys Rev Lett, 2012, 108:042504.
[35]	GARCIA RUIZ R F, GORGES C, BISSELL M, et al. J Phys G:Nucl Part Phys, 2017, 44:044003.
[36]	DE GROOTE R P, BILLOWES J, BINNERSLEY C L, et al. Phys Rev C, 2017, 96:041302.
[37]	LYNCH K M, BILLOWES J, BISSELL M L, et al. Phys Rev X, 2014, 4:011055.
[38]	DE GROOTE R P, BUDINČEVIĆ I, BILLOWES J, et al. Phys Rev lett, 2015, 115:132501.
[39]	GARCIA RUIZ R F, VERNON A R, BINNERSLEY C L, et al. Phys Rev X, 2018, 8:041005.
[40]	LYNCH K M, WILKINS S G, BILLOWES J, et al. Phys Rev C, 2018, 97:024309.
[41]	BEHR J A, GWINNER G. J Phys G:Nucl Part Phys, 2009, 36:033101.
[42]	WANG L B, MUELLER P, BAILEY K, et al. Phys Rev Lett, 2004, 93:142501.
[43]	MUELLER P, SULAI I A, VILLARI A C C, et al. Phys Rev Lett, 2007, 99:252501.
[44]	PARKER R H, DIETRICH M R, KALITA M R, et al. Phys Rev Lett, 2015, 114:233002.
[45]	JIANG W, BAILEY K, LU Z-T, et al. Geochim Cosmochim Acta, 2012, 91:1.
[46]	XIA X W, LIM Y, ZHAO P W, et al. Atom Data Nucl Data Tables, 2018, 121:1.
[47]	WADA M, TAKAMINE A, OKADA K, et al. AIP Conf Proc, 2009, 1120:109.
[48]	YANG X F, TAKESHI F, TAKASHI W, et al. Phys Rev A, 2014, 90:052516.
[49]	LIU W P, BAI X X, ZHOU S H, et al. Phys Rev Lett, 1996, 77:611.
[50]	SUN Z, ZHAN W L, GUO Z Y, et al. Nucl Instr and Meth A, 2003, 503:496.
[51]	ZHOU X H. Nuclear Physics Review, 2018, 35:339.
[52]	XIAO G Q, XU H S, WANG S C. Nuclear Physics Review, 2017, 34:275. (in Chinese). (肖国青, 徐瑚珊, 王思成. 原子核物理评论, 2017, 34:275.)
[53]	YE Y L. EPJ Web Conf, 2018, 178:01005.

点击查看大图

计量

文章访问数: 1892
HTML全文浏览量: 274
PDF下载量: 210
被引次数: 0

用于核物理研究的精密激光谱技术的发展和展望

doi: 10.11804/NuclPhysRev.36.02.161

1. 北京大学物理学院和核物理与核技术国家重点实验室, 北京 100871;

2. 兰州大学核科学与技术学院, 兰州 730000

基金项目: 国家重点研发计划项目（2018YFA0404403）；国家自然科学基金面上项目（11875073）

作者简介:
刘永超(1997-),男,山东青岛人,准博士研究生,从事粒子物理与原子核物理研究;E-mail:ychliu2015@lzu.edu.cn

通讯作者: 杨晓菲,E-mail:xiaofei.yang@pku.edu.cn

收稿日期: 2018-11-29
修回日期: 2019-03-03
刊出日期: 2019-06-20

中图分类号: O571.3

关键词:

摘要: 原子核基本性质（自旋、质量、寿命、磁矩、电四极矩和电荷半径等）与原子核的内在结构密切相关，是检验和发展原子核理论模型的重要依据。实验上可以通过多学科交叉的精密激光谱技术测量原子核外电子的超精细结构和同位素移位，来模型独立地提取原子核的自旋、磁矩、电四极矩和电荷均方根半径等多个核物理参量。这些基本性质的系统测量可以用于探索不稳定原子核中展现出来的新奇的物理现象与规律。近年来，为了测量产额更低的丰中子核的基本性质，激光谱技术不断更新和发展，以实现高分辨、高效率测量。本文详细介绍了激光谱测量的基本原理以及由此发展起来的用于不稳定原子核结构研究的各类互补的激光谱学技术，如共线激光谱（高分辨率低灵敏度）、在源激光谱（高灵敏度低分辨率）、共线共振电离谱（高分辨率高灵敏度）等激光谱技术，以及在不同核区的测量优势和局限。最后结合我国正在发展和规划中的新一代放射性核束装置，讨论精密激光谱技术在国内的发展以及在核物理研究中的应用。

English Abstract

Development and Prospect of Precision Laser Spectroscopy Techniques for Nuclear Physics Study

1. School of Physics and State Key Laboratory of Nuclear Physics and Technology, Peking University, Beijing 100871, China;

2. School of Nuclear Science and Technology, Lanzhou University, Lanzhou 730000, China

Funds: National Key R&D Program of China (2018YFA0404403); National Natural Science Foundation of China (11875073)

Received Date: 2018-11-29
Rev Recd Date: 2019-03-03
Publish Date: 2019-06-20

Keywords:

Abstract: The nuclear properties (spin, mass, life-time, magnetic moment, electric quadrupole moment and charge radius) of the ground and long-lived states of unstable nuclei can be used to explore the exotic nuclear structure phenomenon, and also will be a prominent input for the nuclear theory methods and nuclear interactions. Experimentally, we can nuclear-model independently determine the nuclear spins, magnetic moments, electric quadrupole moments and mean square charge radii simultaneously from hyperfine structure and isotope shift, measured with the interdisciplinary laser spectroscopy techniques. In recent years, with the continuous efforts, various laser spectroscopy techniques with high resolution and high efficiency have been developed in order to study the short-lived isotopes produced at the radioactive ion beam facilities with very low production yield. Here, we will introduce the basic principle of laser spectroscopy measurement and discuss in detail the various complementary laser spectroscopy techniques developed for the nuclear structure study of unstable isotopes. The advantages and disadvantages of these techniques, such as collinear laser spectroscopy (high resolution, low sensitivity), in-source laser spectroscopy (high sensitivity, low resolution), as well as collinear resonant ionization (high resolution, high sensitivity), are discussed regarding to the resolution and sensitivity, which is highly related to the application of the technique in different mass region of nuclear chart. In addition, future plan and prospect on the development of the precision laser spectroscopy techniques will be discussed, which, with the hope, will be used for nuclear physics study at the next-generation facilities constructed and planed in China.

刘永超, 白世伟, 杨晓菲. 用于核物理研究的精密激光谱技术的发展和展望[J]. 原子核物理评论, 2019, 36(2): 161-169. doi: 10.11804/NuclPhysRev.36.02.161

引用本文:

刘永超, 白世伟, 杨晓菲. 用于核物理研究的精密激光谱技术的发展和展望[J]. 原子核物理评论, 2019, 36(2): 161-169. doi: 10.11804/NuclPhysRev.36.02.161

Citation:

全文HTML

参考文献 (53)

下载: 全尺寸图片幻灯片

返回文章

用微信扫码二维码

分享至好友和朋友圈

留言板

用于核物理研究的精密激光谱技术的发展和展望

doi: 10.11804/NuclPhysRev.36.02.161

作者简介: 刘永超(1997-),男,山东青岛人,准博士研究生,从事粒子物理与原子核物理研究;E-mail:ychliu2015@lzu.edu.cn

通讯作者: 杨晓菲,E-mail:xiaofei.yang@pku.edu.cn

Development and Prospect of Precision Laser Spectroscopy Techniques for Nuclear Physics Study

计量

出版历程

用于核物理研究的精密激光谱技术的发展和展望

doi: 10.11804/NuclPhysRev.36.02.161

1. 北京大学物理学院和核物理与核技术国家重点实验室, 北京 100871; 2. 兰州大学核科学与技术学院, 兰州 730000

作者简介: 刘永超(1997-),男,山东青岛人,准博士研究生,从事粒子物理与原子核物理研究;E-mail:ychliu2015@lzu.edu.cn

通讯作者: 杨晓菲,E-mail:xiaofei.yang@pku.edu.cn

English Abstract

Development and Prospect of Precision Laser Spectroscopy Techniques for Nuclear Physics Study

1. School of Physics and State Key Laboratory of Nuclear Physics and Technology, Peking University, Beijing 100871, China; 2. School of Nuclear Science and Technology, Lanzhou University, Lanzhou 730000, China

全文HTML

目录

作者简介:
刘永超(1997-),男,山东青岛人,准博士研究生,从事粒子物理与原子核物理研究;E-mail:ychliu2015@lzu.edu.cn

1. 北京大学物理学院和核物理与核技术国家重点实验室, 北京 100871;

2. 兰州大学核科学与技术学院, 兰州 730000

作者简介:
刘永超(1997-),男,山东青岛人,准博士研究生,从事粒子物理与原子核物理研究;E-mail:ychliu2015@lzu.edu.cn

1. School of Physics and State Key Laboratory of Nuclear Physics and Technology, Peking University, Beijing 100871, China;

2. School of Nuclear Science and Technology, Lanzhou University, Lanzhou 730000, China