类氦氪离子共振转移激发过程的理论研究

doi:10.7523/j.issn.1002-1175.2013.02.005

中国科学院大学学报 ›› 2013, Vol. 30 ›› Issue (2): 172-178.DOI: 10.7523/j.issn.1002-1175.2013.02.005

类氦氪离子共振转移激发过程的理论研究

胡骁骊¹, 屈一至¹, 王建国²

1. 中国科学院研究生院材料科学与光电技术学院, 北京 100049;
2. 北京应用物理与计算数学研究所, 北京 100088

收稿日期:2012-03-26 修回日期:2012-04-20 发布日期:2013-03-15
通讯作者: 屈一至
基金资助:
国家自然科学基金(1179041)和国家自然科学基金委-中国工程物理研究院联合基金(NSAF10876043)资助

Theoretical study on resonant transfer excitation processes for helium-like krypton ion

HU Xiao-Li¹, QU Yi-Zhi¹, WANG Jian-Guo²

1. College of Materials Science and Opto-Electronic Technology, Graduate University, Chinese Academy of Sciences, Beijing 100049, China;
2. Institute of Applied Physics and Computational Mathematics, Beijing 100088, China

Received:2012-03-26 Revised:2012-04-20 Published:2013-03-15

摘要/Abstract

摘要：

应用相对论组态相互作用方法,计算了类氦氪离子(Kr³⁴⁺)经过1s2lnl'(n=2,3,…,15)态的双电子复合截面,然后在冲量近似下计算了Kr³⁴⁺与CH₄、NH₃、H₂O和HF共振转移激发(RTE)截面.在低动量端,CH₄、NH₃、H₂O和HF的康普顿轮廓依次减小.相比Kr³⁴⁺与CH₄的RTE截面,Kr³⁴⁺与NH₃、H₂O和HF的RTE截面在第1个峰位处截面值分别减小10.7%、23.3%和33.6%,在第2个峰位处截面值分别减小6.0%、12.3%和18.9%.同时,RTE峰的宽度依次增加,这表明随着C、N、O和F的核电荷数增加,库仑作用导致电子动量空间分布变大.

关键词: 双电子复合, 共振转移激发, 康普顿轮廓

Abstract:

The relativistic configuration interaction method is employed to investigate the resonant transfer excitation (RTE) processes of Kr³⁴⁺ colliding with CH₄, NH₃, H₂O, and HF targets under the impulse approximation. Compared to the case of CH₄, the RTE cross sections of NH₃, H₂O, and HF targets reduce by 10.7%, 23.3%, and 33.6% in the first peak position and by 6.0%, 12.3%, and 18.9% in the second peak position, respectively, due to the decrease in Compton profiles in the small momentum region. On the other hand, the width of the peaks increases from CH₄ to HF, which indicates that strong Coulomb effect leads to the broader momentum distribution.

Key words: dielectronic recombination, resonant transfer excitation, Compton profile

中图分类号:

O561

胡骁骊, 屈一至, 王建国. 类氦氪离子共振转移激发过程的理论研究[J]. 中国科学院大学学报, 2013, 30(2): 172-178.

HU Xiao-Li, QU Yi-Zhi, WANG Jian-Guo. Theoretical study on resonant transfer excitation processes for helium-like krypton ion[J]. , 2013, 30(2): 172-178.

参考文献

[1] Fuchs T,Biedermann C,Radtke R, et al.Channel-specific dielectronic recombination of highly charged krypton[J].Phys Rev A,1998,58(6):4518-4525.

[2] Tanis J,Bernstein E,Clark M W, et al.Resonant transfer and excitation: dependence on projectile charge state and target-electron momentum distribution[J].Phys Rev A,1986,34(3):2543-2546.

[3] Tanis J,Bernstein E,Graham W, et al.Resonant electron transfer and excitation in two-, three-, and four-electron ₂₀Ca^q+ and ₂₃V^q+ ions colliding with helium[J]. Phys Rev Lett,1984,53(27):2551-2554.

[4] Ma X,Mokler P,Bosch F, et al.Electron-electron interaction studied in strong central fields by resonant transfer and excitation with H-like U ions[J].Phys Rev A,2003,68(042712):1-10.

[5] Dong C Z,Fu Y B.Theoretical studies of dielectronic recombination and resonant transfer excitation for highly ionized Cu¹⁸⁺ ions[J].Chin Phys,2006,55:107-111(in Chinese).董晨钟,符彦飙.高离化态Cu¹⁸⁺离子的双电子复合及共振转移激发过程的理论研究[J].物理学报,2006,55:107-111.

[6] Dong C Z,Wang J G,Qu Y Z, et al.Dielectronic recombination and resonant transfer excitation for Ca¹⁹⁺ ions[J].Physica Scripta,1999,1999:301-302.

[7] Hehre W J,Ditchfield R, Pople J A.Self-consistent molecular orbital methods. XII. further extensions of Gaussian-type basis sets for use in molecular orbital studies of organic molecules[J].J Chem Phys,1972,56: 2257-2261.

[8] Krishnan R,Binkley J,Seeger R, et al.Self-consistent molecular orbital methods. XX. A basis set for correlated wave functions[J].J Chem Phys,1980,72:650-654.

[9] Kendall R A,Dunning Jr T H, Harrison R J.Electron affinities of the first-row atoms revisited. Systematic basis sets and wave functions[J].J Chem Phys,1992,96:6796-6806.

[10] Dunning Jr T H.Gaussian basis sets for use in correlated molecular calculations. I. The atoms boron through neon and hydrogen[J].J Chem Phys,1989,90:1007-1023.

[11] Woon D E, Dunning Jr T H.Gaussian basis sets for use in correlated molecular calculations. IV. Calculation of static electrical response properties[J].J Chem Phys,1994,100:2975-2988.

[12] Gu M F.Indirect X-ray line-formation processes in iron L-shell ions[J].Astrophy J,2003,582:1241-1250.

[13] Biedermann C,Fuchs T,Liebisch P, et al.X-ray spectroscopic measurements of dielectronic recombination of highly charged krypton ions[J].Physica Scripta,1999,1999:303-304.

[14] Brandt D.Resonant transfer and excitation in ion-atom collisions[J].Phys Rev A,1983,27:1314-1318.

[15] Eisenberger P.Electron momentum density of He and H₂: Compton X-Ray scattering[J].Phys Rev A,1970,2:1678-1686.

[16] Brion C,Cooper G,Zheng Y, et al. Imaging of orbital electron densities by electron momentum spectroscopy-a chemical interpretation of the binary (e, 2e) reaction[J].Chem Phys,2001,270:13-30.

[17] Frisch M,Trucks G,Schlegel H, et al.Gaussian 98, revision A. 7[CP].Pittsburgh, PA:Gaussian Inc,1998.

[18] Linstrom P J, Mallard W.The NIST Chemistry WebBook[DB/OL].(1997)[2012-02-25]. http://webbook.nist.gov/chemistry.

[19] Ahlenius T, Lindner P.Compton profiles and momentum expectation values for the H₂O, NH₃ and CH₄ molecules[J].Chem Phys Lett,1975,34:123-127.

[20] Hu X L,Qu Y Z,Zhang S B, et al.Dielectronic recombination and resonant transfer excitation processes for helium-like krypton[J].Chin Phys B, 2012, 21(10):220-226.

类氦氪离子共振转移激发过程的理论研究

Theoretical study on resonant transfer excitation processes for helium-like krypton ion

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