Fe^(23+)离子1s^22s-1s^2np的跃迁能和偶极振子强度被引量：8

Transition energy and dipole oscillator strength for the 1s^22s-1s^2np of Fe^(23+) ion

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摘要用全实加关联方法计算了类锂Fe23+离子1s22s-1s2np(2≤n≤9)的跃迁能和1s2np(n≤9)态的精细结构.依据单通道量子亏损理论,确定了Rydberg系列1s2np的量子数亏损.用这些作为能量的缓变函数的量子亏损,可以实现对任意高激发态(n≥10)的能量的可靠预言.用在计算能量过程中确定的波函数,计算了Fe23+离子1s22s-1s2np(2≤n≤9)跃迁的振子强度.将这些分立态振子强度与单通道量子亏损理论相结合,得到该离子从基态到电离阈附近高激发束缚态间的偶极跃迁振子强度以及束缚态-连续态跃迁的振子强度密度,从而将Fe23+离子的这一重要光谱特性的理论预言外推到整个能域. The transition energy of 1s^2 2s-1s^2 np（2≤n≤9） and fine structure splitting of 1s2nP（ 1= s, p; n≤9） states for lithium-like Fe^23＋ .ion are calculated by using the full-core plus correlation method. The quantum defect of Rydberg series 1 s^2 np is determined according tO the single-channel quantum defect theory. The energies of any highly excited strtes With （n≥10） for this series can be reliably predicted using the quantum defects which are function of energy： The dipole oscillator strengths for the 1s^2 2s-1s^2 np （ n 49） transitions of Fe^23＋ ion are calculated with the energies and FCPC wave functions obtained above. Combining the quantum defect theory with the discrete osc.llator strengths, the discrete oscillator strengths for the transitions from initial state ls22s to highly excited states （n≥10） and the oscillator strengths density corresponding to the bound-free transitions are obtained.

作者王治文吉莉胡木宏刘鑫吕梁

机构地区辽宁师范大学物理与电子技术学院

出处《原子与分子物理学报》 CAS CSCD 北大核心 2007年第2期232-236,共5页 Journal of Atomic and Molecular Physics

基金国家自然科学基金资助项目(10474029)

关键词 Fe^23+离子跃迁能精细结构量子亏损振子强度 Fe^23＋ ion, transition energy, fine structure splitting, quantum defect, oscillator strength

分类号 O562.1 [理学—原子与分子物理]

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参考文献17

1Gillaspy J D.Highly charged ions[J].J.Phys.B,2001,34:R93
2Wang Z W,Han Q J,Hu M H,et al.Energy and oscillator strength of V^20+ ion[J].Front.Phys.China,2006,1:102
3Chung K T.Ionization potential of the lithium like 1s^22s states from lithium to neon[J].Phys.Rev.A,1991,44:5421
4Chung K T.Ionization potential of the lithiumlike 1s^22s states from Na Ⅸ to Ca ⅩⅧ[J].Phys.Rev.A,1992,45:7766
5Wang Z W,Zhu X W,Chung K T.Energy and fine structure of 1s^2np (n = 2,3,4 and 5) states for the lithium isoelectronic sequence[J].Phys.Scr.,1993,47:64
6Wang Z W,Yang Di,Hu M H,et al.Transition energy and oscillator strength of Sc^18+ ion[J].Chin.Phys.,2005,14:1559
7张楠,胡木宏,王治文.Sc^(+18)离子1s^23d-1s^2nf的跃迁能和偶极振子强度[J].原子与分子物理学报,2005,22(4):597-601. 被引量：10
8董行,胡木宏,王治文.Ti^19＋离子1s^23d-1s^2nf的跃迁能和振子强度[J].原子与分子物理学报,2006,23(B04):26-28. 被引量：4
9王治文,韩秋菊,杨迪,李金英.V^(+20)离子的能量和偶极振子强度[J].原子与分子物理学报,2005,22(2):211-216. 被引量：5
10宋连鹏,王治文,胡木宏.V^(20+)离子1s^23d-1s^2nf的跃迁能和振子强度[J].原子与分子物理学报,2006,23(2):201-204. 被引量：6

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二级参考文献32

1王治文,韩秋菊,杨迪,李金英.V^(+20)离子的能量和偶极振子强度[J].原子与分子物理学报,2005,22(2):211-216. 被引量：5
2王治文,李金英,杨迪,韩秋菊.Ti^(+19)离子的能量和振子强度[J].辽宁师范大学学报（自然科学版）,2005,28(2):165-169. 被引量：4
3张楠,胡木宏,王治文.Sc^(+18)离子1s^23d-1s^2nf的跃迁能和偶极振子强度[J].原子与分子物理学报,2005,22(4):597-601. 被引量：10
4Chung K T. Ionization potential of the lithiumlike 1s^22s states from lithium to neon [J]. Phys. Rev., 1991, A44(9): 5 421～5 433.
5Chung K T. Ionization potential of the lithiumlike 1s^22s states from Na Ⅸ to Ca ⅩⅧ [J]. Phys. Rev., 1992, A45(11): 7 766～7 773.
6Wang Z W, Zhu X W ,Chung K T. Energy of 1s^2ns (n=3,4 and 5) states for the lithium isoelectronic sequence [J]. Phys. Rev., 1992, A46(11): 6 914～6 919.
7Wang Z W, Zhu X W ,Chung K T. Energy and fine structure of 1s^2np(n=2,3,4 and 5) states for the lithium isoelectronic sequence [J]. Physica Scripta. 1993, 47: 64～74.
8Wang Z W, Chung K T. Dipole polarizabilities for the ground states of lithium-like systems from Z=3 to 50[J]. J. Phys., 1994, B27: 855～864.
9Bethe H A, Salpeter E E. Quantum mechanics of one and two-electron atoms[M]. Berlin: Springer-Verlag, 1977.
10Cowan R D. The theory of atomic structure and spectra[M]. Berkeley: University of California Press, 1981.