考虑自旋-轨道耦合效应下SeH<sup>–</sup>阴离子的光谱和跃迁性质

万明杰; 柳福提; 黄多辉

doi:10.7498/aps.70.20201413

摘要

采用高精度的从头算方法研究了SeH^–阴离子的基态(X¹Σ⁺)和低激发(a³Π, A¹Π, b³Σ⁺, 2¹Σ⁺)的势能曲线、偶极矩和跃迁偶极矩. 在计算中考虑了价-芯(CV)电子关联、Davidson修正、标量相对论修正和自旋-轨道耦合效应(SOC). 考虑了SOC效应后, $ {{\rm{b}}^3}\Sigma _{{0^ - }}^ + $和$ {{\rm{b}}^3}\Sigma _{{1}}^ + $态变为了弱束缚态. 计算得到$ {{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, ${{\rm{a}}^3}{\Pi _{{0^ + }}} \leftrightarrow $${{\rm{X}}^1}\Sigma _{{0^ + }}^ +$和$ {{\rm{A}}^1}{\Pi _1} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $跃迁具有很大的跃迁偶极矩. 这三种跃迁都同时具有高对角分布的弗兰克-康登因子f₀₀及振动分支比R₀₀. 计算得到了$ {{\rm{a}}^3}{\Pi _{{1}}}$, $ {{\rm{a}}^3}{\Pi _{{{{0}}^{{ + }}}}}$和$ {{\rm{A}}^1}{\Pi _{{1}}}$激发态的自发辐射寿命都很短, 能够实现对SeH^–阴离子的快速激光冷却. $ {{\rm{A}}^1}{\Pi _1} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $跃迁为三能级跃迁, 中间态的存在对构建准闭合的循环能级的影响可以忽略. 驱动$ {{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, $ {{\rm{a}}^3}{\Pi _{{0^ + }}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $和$ {{\rm{A}}^1}{\Pi _1} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $跃迁进行激光冷却SeH^–阴离子的激光波长都在可见光范围内. 本文的结果为以后激光冷却SeH^–阴离子的实验提供了部分理论参考.

关键词:

Abstract

Potential energy curves (PECs), permanent dipole moments (PDMs) and transition dipole moments (TMDs) of five Λ-S states of SeH⁻ anion are calculated by the MRCI + Q method with ACVQZ-DK basis set. The core-valence corrections, Davidson corrections, scalar relativistic corrections, and spin-orbit coupling (SOC) effects are also considered. In the CASSCF step, Se(1s2s2p3s3p) shells are put into the frozen orbitals, which are not optimized. Six molecular orbitals are chosen as active space, including H(1s) and Se(4s4p5s) shells, and eight electrons are distributed in a (4, 1, 1, 0) active space, which is referred to as CAS (8, 6), and the Se(3d) shell is selected as a closed-shell, which keeps doubly occupation. In the MRCI step, the remaining Se(3d) shell is used for core-valence calculations of SeH⁻ anion. The SOC effects are taken into account in the one- and two- electron Breit-Pauli operators.The b³Σ⁺ state is a repulsive state. Other excited states are bound, and all states possess two potential wells. The $ {{\rm{b}}^{{3}}}\Sigma _{{0^ - }}^ + $ and $ {{\rm{b}}^3}\Sigma _{{1}}^ + $ both turn into bound states when the SOC effect is considered. All spectroscopic parameters of Λ-S states and Ω states are reported for the first time. The TDMs of the $ {{\rm{A}}^{{1}}}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $, $ {{\rm{a}}^{{3}}}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, $ {{\rm{a}}^{{3}}}{\Pi _{{{{0}}^{{ + }}}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, $ {{\rm{A}}^{{1}}}{\Pi _{{1}}} \leftrightarrow {{\rm{a}}^{{3}}}{\Pi _{{1}}}$, and $ {{\rm{A}}^{{1}}}{\Pi _{{1}}} \leftrightarrow {{\rm{a}}^{{3}}}{\Pi _{{{{0}}^{{ + }}}}}$ transitions are also calculated. The TDMs of the $ {{\rm{A}}^{{1}}}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $ and $ {{\rm{a}}^{{3}}}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $ transitions are large in the Franck-Condon region, which are about –2.05 Debye (D) and 1.45 D at R_e. Notably, the TDMs of the $ {{\rm{a}}^3}{\Pi _{{{{0}}^{{ + }}}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $ transition cannot be ignored. The value of TDM at R_e equals –0.15 D.Based on the accurately PECs and PDMs, the values of Franck-Condon factor f_υ′υ″, vibrational branching ratio R_υ′υ″ and radiative coefficient of the $ {{\rm{a}}^{{3}}}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $, $ {{\rm{a}}^{{3}}}{{{\Pi }}_{{{{0}}^{{ + }}}}} \leftrightarrow {{\rm{X}}^{{1}}}{{\Sigma }}_{{0^ + }}^ + $, and $ {{\rm{A}}^{{1}}}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $ transitions are also calculated. Highly diagonally distributed Franck-Condon factor f₀₀ and the values of vibrational branching ratio R₀₀ of the $ {{\rm{a}}^{{3}}}{\Pi _{{1}}}(\upsilon ') \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + (\upsilon '')$, $ {{\rm{a}}^{{3}}}{\Pi _{{0^ + }}}(\upsilon ') \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + (\upsilon '')$, and $ {{\rm{A}}^1}{\Pi _1}(\upsilon ') \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + (\upsilon '')$ transitions are obtained, respectively. Spontaneous radiation lifetimes of the $ {{\rm{a}}^3}{\Pi _{{1}}}$, $ {{\rm{a}}^3}{\Pi _{{{{0}}^{{ + }}}}}$, and $ {{\rm{A}}^1}{\Pi _{{1}}}$ excited states are all short for rapid laser cooling. The influences of intervening states of the $ {{\rm{A}}^1}{\Pi _1}(\upsilon ') \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + (\upsilon '')$ transition can be ignored. The proposed cooling wavelengths using the $ {{\rm{a}}^3}{\Pi _{{1}}}(\upsilon ') \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + (\upsilon '')$, $ {{\rm{a}}^{{3}}}{\Pi _{{0^ + }}}(\upsilon ') \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + (\upsilon '')$, and $ {{\rm{A}}^1}{\Pi _1}(\upsilon ') \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + (\upsilon '')$ transitions are all in the visible region.

Keywords:

作者及机构信息

宜宾学院理学部, 宜宾　644007

通信作者: 黄多辉, hdhzhy912@163.com

基金项目: 宜宾学院预研项目(批准号: 2019YY06)和计算物理四川省高等学校重点实验室开放基金(批准号: YBXYJSWL-ZD-2020-001) 资助的课题

Authors and contacts

Faculty of Science, Yibin University, Yibin 644007, China

Corresponding author: Huang Duo-Hui, hdhzhy912@163.com

Funds: Project supported by the Pre-Research Project of Yibin University, China (Grant No. 2019YY06) and the Open Research Fund of Computational Physics Key Laboratory of Sichuan Province, Yibin University, China (Grant No. YBXYJSWL-ZD-2020-001)

文章全文 : translate this paragraph

参考文献

[1]	Shuman E S, Barry J F, DeMille D 2010 Nature 467 820 Google Scholar
[2]	Hummon M T, Yeo M, Stuhl B K, Collopy A L, Xia Y, Ye J 2013 Phys. Rev. Lett. 110 143001 Google Scholar
[3]	Zhelyazkova V, Cournol A, Wall T E, Matsushima A, Hudson J J, Hinds E A, Tarbutt M R, Sauer B E 2014 Phys. Rev. A 89 053416 Google Scholar
[4]	Gao Y, Gao T 2014 Phys. Rev. A 90 052506 Google Scholar
[5]	You Y, Yang C L, Wang M S, Ma X G, Liu W W 2015 Phys. Rev. A 92 032502 Google Scholar
[6]	Cui J, Xu J G, Qi J X, Dou G, Zhang Y G 2018 Chin. Phys. B 27 103101 Google Scholar
[7]	Wan M J, Yuan D, Jin C G, Wang F H, Yang Y J, Yu Y, Shao J X 2016 J. Chem. Phys. 145 024309 Google Scholar
[8]	张云光, 张华, 窦戈, 徐建刚 2017 66 233101 Google Scholar Zhang Y G, Zhang H, Dou G, Xu J G 2017 Acta Phys. Sin. 66 233101 Google Scholar
[9]	Xu L, Wei W, Xia Y, Deng L Z, Yin J P 2017 Chin. Phys. B 26 033702 Google Scholar
[10]	Yzombard P, Hamamda M, Gerber S, Doser M, Comparat D 2015 Phys. Rev. Lett. 114 213001 Google Scholar
[11]	Zhang Q Q, Yang C L, Wang M S, Ma X G, Liu W W 2017 Spectrochim. Acta. Part A 185 365 Google Scholar
[12]	Zhang Q Q, Yang C L, Wang M S, Ma X G, Liu W W 2017 Spectrochim. Acta. Part A 182 130 Google Scholar
[13]	Zeid I, Abdallah R A, El Kork N, Korek M 2020 Spectrochim. Acta. Part A 224 117461 Google Scholar
[14]	Wan M J, Huang D H, Yu Y, Zhang Y G 2017 Phys. Chem. Chem. Phys. 19 27360 Google Scholar
[15]	万明杰, 李松, 金成国, 罗华锋 2019 68 063103 Google Scholar Wan M J, Li S, Jin C G, Luo H F 2019 Acta. Phys. Sin. 68 063103 Google Scholar
[16]	Deng B L, Wan M J, Zhao X F, Tang K, Zhang X Q 2020 Spectrochim. Acta. Part A 227 117684 Google Scholar
[17]	Stoneman R C, Larson D J 1987 Phys. Rev. A 35 2928 Google Scholar
[18]	Brown J M, Fackerell A D 1982 Physica. Scripta. 25 351 Google Scholar
[19]	Balasubramanian K, Liao M Z, Han M 1987 Chem. Phys. Lett. 139 551 Google Scholar
[20]	Binning Jr R C, Curtiss L A 1990 J. Chem. Phys. 92 1860 Google Scholar
[21]	Werner H J, Knowles P J, Knizia G, et al. 2010 MOLPRO, a Package of ab initio Programs (version 2010.1)
[22]	Knowles P J, Werner H J 1985 J. Chem. Phys. 82 5053 Google Scholar
[23]	Werner H J, Meyer W 1980 J. Chem. Phys. 73 2342 Google Scholar
[24]	Werner H J, Knowles P J 1988 J. Chem. Phys. 89 5803 Google Scholar
[25]	Knowles P J, Werner H J 1988 Chem. Phys. Lett. 145 514 Google Scholar
[26]	Laughoff S R, Davidson E R 1974 Int. J Quantum. Chem. 8 61 Google Scholar
[27]	Douglas N, Kroll N M 1974 Ann. Phys. 82 89 Google Scholar
[28]	Hess B A 1986 Phys. Rev. A 33 3742 Google Scholar
[29]	Berning A, Schweizer M, Werner H J, Knowles P J, Palmieri P 2000 Mol. Phys. 98 1823 Google Scholar
[30]	DeYonker N J, Peterson K A, Wilson A K 2007 J. Phys Chem A 111 11383 Google Scholar
[31]	Dunning Jr T H 1989 J. Chem. Phys. 90 1007 Google Scholar
[32]	Le Roy R J 2007 LEVEL 8.0: a Computer Program for Solving the Radial Schröinger Equation for Bound and Quasibound Levels (Waterloo: University of Waterloo) Chemical Physics Research Report CP-663
[33]	Huber K, Herzberg G 1979 Molecular Spectra and Molecular Structure Vol. 4. Constants of Diatomic Molecules (New York: Van Nostrand Reinhold) p586
[34]	Moore C E 1971 Atomic Energy Levels (Vol. 1) (Washington, DC: US Govt Printing Office) pp2, 150
[35]	Lykke K R, Murray K K, Lineberger W C 1991 Rhys. Rev. A 43 6104 Google Scholar
[36]	Hotop H, Lineberger W C 1985 J. Phys. Chem. Ref. Data 14 731 Google Scholar
[37]	Lane I C 2015 Phys. Rev. A 92 022511 Google Scholar
[38]	You Y, Yang C L, Zhang Q Q, Wang M S, Ma X G, Wang W W 2016 Phys. Chem. Chem. Phys. 18 19838 Google Scholar

施引文献

图 1 X¹Σ⁺, a³Π, A¹Π, b³Σ⁺和2¹Σ⁺电子态的势能曲线

Fig. 1. Potential energy curves of the X¹Σ⁺, a³Π, A¹Π, b³Σ⁺, and 2¹Σ⁺ states.

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图 2 9个Ω电子态的势能曲线

Fig. 2. Potential energy curves of nine Ω states.

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图 3 ${{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, ${{\rm{a}}^3}{\Pi _{{0^ + }}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, ${{\rm{A}}^{{1}}}{\Pi _1} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $, ${{\rm{A}}^1}{\Pi _1} \leftrightarrow {{\rm{a}}^{{3}}}{\Pi _1}$和${{\rm{A}}^{{1}}}{\Pi _1} \leftrightarrow {{\rm{a}}^{{3}}}{\Pi _{{{{0}}^{{ + }}}}}$跃迁的跃迁偶极矩

Fig. 3. Transition dipole moments of the ${{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, ${{\rm{a}}^3}{\Pi _{{0^ + }}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, ${{\rm{A}}^{{1}}}{\Pi _1} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $, ${{\rm{A}}^1}{\Pi _1} \leftrightarrow {{\rm{a}}^{{3}}}{\Pi _1}$, and ${{\rm{A}}^{{1}}}{\Pi _1} \leftrightarrow {{\rm{a}}^{{3}}}{\Pi _{{{{0}}^{{ + }}}}}$ transition.

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图 4 激光冷却SeH^–阴离子的方案　(a)${{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $跃迁; (b) ${{\rm{a}}^3}{\Pi _{{0^ + }}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $跃迁

Fig. 4. Proposed laser cooling scheme: (a) Using the ${{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $ transition; (b) using the ${{\rm{a}}^3}{\Pi _{{0^ + }}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $ transition.

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图 5 采用${{\rm{A}}^1}{\Pi _1} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $跃迁进行激光冷却SeH^–阴离子的方案

Fig. 5. Proposed laser cooling scheme by using the ${{\rm{A}}^{{1}}}{\Pi _1} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $ transition.

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表 1 Λ-S的光谱常数

Table 1. Spectroscopic parameters of the Λ-S states.

Λ-S态	来源		R_e/Å	ω_e/cm^–1	ω_eχ_e/cm^–1	B_e/cm^–1	D_e/eV	T_e/cm^–1
X¹Σ⁺	ACVQZ-DK		1.4694	2300.77	46.10	7.8507	3.487	0
	AVQZ-DK		1.4614	2380.32	45.57	7.9326	3.711
	实验^[17]		1.4696 ^a			7.7289 ^c
	实验^[17]		1.4806 ^b			7.7289 ^c
a³Π	本文工作	第一势阱	1.4778	2206.52	123.45	7.8428	0.519	20642.90
a³Π	本文工作	第二势阱	2.1787	839.87	49.66	3.44016	0.450	24549.11
A¹Π	本文工作	第一势阱	1.4726	2373.65	127.14	7.8391	0.734	21240.75
A¹Π	本文工作	第二势阱	2.2780	437.62	44.07	3.0932	0.147	26997.57
b³Σ⁺	本文工作		repulsive
2¹Σ⁺	本文工作	第一势阱	1.6188	1336.45	—	6.1955	0.228	51684.73
2¹Σ⁺	本文工作	第二势阱	4.0808	198.90	9.96	1.0190	0.135	46349.30
注: ^a 为SeH分子基态的平衡核间距的实验值来源于文献[18]; ^b为SeH分子基态的平衡核间距的实验值来源于文献[33], 结果不准确; ^c 为采用最小二乘法得到转动惯量B.

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表 2 第VI主簇氢化物阴离子基态的光谱常数

Table 2. Spectroscopic parameters of the ground state X¹Σ⁺ of the Group VI-hydride anions.

阴离子	来源	R_e/Å	ω_e/cm^–1	ω_eχ_e/cm^–1	B_e/cm^–1	D_e/eV
OH^–	文献[14]	0.9645	3722.10	87.93	19.1111	4.9857
SH^–	文献[15]	1.3435	2622.04	46.66	9.5590	3.8793
SeH^–	本文工作	1.4694	2300.77	46.10	7.8507	3.487
TeH^–	文献[16]	1.6631	1973.73	36.8272	6.0996	3.0568

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表 3 Ω态的离解关系

Table 3. Calculated dissociation relationships of the Ω states.

离解通道	分子态(Ω)	相对能量/cm^–1
离解通道	分子态(Ω)	ACVQZ-DK	AVQZ-DK	实验^[34-36]
Se^–(²P_3/2) + H(²S_1/2)	2, 1, 1, 0⁺, 0^–	0	0	0
Se^–(²P_1/2) + H(²S_1/2)	1, 0⁺, 0^–	2303.77	2192.98	—
Se(¹D₂) + H^–(¹S₀)	0⁺	20032.24	19047.45	19790.88

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表 4 Ω电子态的光谱常数

Table 4. Spectroscopic parameters of the Ω states.

Ω态		R_e/Å	ω_e/cm^–1	ω_eχ_e/cm^–1	B_e/cm^–1	D_e/eV	T_e/cm^–1
${{\rm{X}}^1}\Sigma _{{0^ + }}^ + $		1.4694	2301.31	47.01	7.8499	3.395	0
${{\rm{a}}^3}{\Pi _2}$	第一势阱	1.4777	2207.22	122.39	7.8416	0.523	19787.17
${{\rm{a}}^3}{\Pi _2}$	第二势阱	2.1739	861.02	52.10	3.4081	0.454	23751.54
${{\rm{a}}^3}{\Pi _{{1}}}$	第一势阱	1.4759	2232.16	111.70	7.8434	0.560	20036.27
${{\rm{a}}^3}{\Pi _{{1}}}$	第二势阱	2.1822	818.11	55.64	3.3929	0.386	24301.10
${{\rm{a}}^3}{\Pi _{{{{0}}^ - }}}$	第一势阱	1.4778	2205.83	124.97	7.8485	0.513	21472.52
${{\rm{a}}^3}{\Pi _{{{{0}}^ - }}}$	第二势阱	2.1986	778.28	73.70	3.4048	0.267	25261.96
${{\rm{a}}^3}{\Pi _{{{{0}}^{{ + }}}}}$	第一势阱	1.4777	2208.03	122.90	7.8422	0.522	21477.12
${{\rm{a}}^3}{\Pi _{{{{0}}^{{ + }}}}}$	第二势阱	2.1619	904.15	49.02	3.4355	0.527	25454.22
${{\rm{A}}^1}{\Pi _{{1}}}$	第一势阱	1.4744	2368.50	144.22	7.8262	0.686	21821.04
${{\rm{A}}^1}{\Pi _{{1}}}$	第二势阱	排斥态
${{\rm{b}}^3}\Sigma _{{0^ - }}^ + $	第一势阱	3.1807	318.89	35.64	1.6988	0.096	28945.41
${{\rm{b}}^3}\Sigma _{{1}}^ + $	第二势阱	3.2046	239.13	30.94	1.6662	0.066	29184.63
${2^1}\Sigma _{{0^ + }}^ + $	第一势阱	1.6190	1332.50	—	6.1895	0.225	51714.58
${2^1}\Sigma _{{0^ + }}^ + $	第二势阱	4.0800	190.57	8.84	1.0190	0.135	46351.94

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表 5 ${{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, ${{\rm{a}}^{{3}}}{\Pi _{{0^ + }}} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $和${{\rm{A}}^1}{\Pi _1} \leftrightarrow $${{\rm{X}}^1}\Sigma _{{0^ + }}^ +$跃迁的辐射系数${A_{\upsilon '\upsilon ''}}$、弗兰克-康登因子${f_{\upsilon '\upsilon ''}}$和振动分支比${R_{\upsilon '\upsilon ''}}$

Table 5. Emission rates ${A_{\upsilon '\upsilon ''}}$, Franck-Condon Factors ${f_{\upsilon '\upsilon ''}}$, branching ratios ${R_{\upsilon '\upsilon ''}}$ of the ${{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $, ${{\rm{a}}^{{3}}}{\Pi _{{0^ + }}} \leftrightarrow {{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $, and ${{\rm{A}}^1}{\Pi _1} \leftrightarrow $ ${{\rm{X}}^1}\Sigma _{{0^ + }}^ +$ transitions.

Index		${{\rm{a}}^3}{\Pi _{{1}}} \leftrightarrow $ ${{\rm{X}}^1}\Sigma _{{0^ + }}^ + $	${{\rm{a}}^{{3}}}{\Pi _{{0^ + }}} \leftrightarrow $ ${{\rm{X}}^{{1}}}\Sigma _{{0^ + }}^ + $	${{\rm{A}}^1}{\Pi _1} \leftrightarrow$ $ {{\rm{X}}^1}\Sigma _{{0^ + }}^ + $
${f_{\upsilon '\upsilon ''}}$	f₀₀	0.9949	0.9922	0.9974
	f₀₁	0.0047	0.0072	0.0025
	f₀₂	0.0004	0.0006	0.0001
	f₁₀	0.0051	0.0079	0.0026
	f₁₁	0.9541	0.9324	0.9792
	f₁₂	0.0337	0.0486	0.0159
${A_{\upsilon '\upsilon ''}}\rm /s$	A₀₀	5.02×10⁶	8.02×10⁴	1.36×10⁷
	A₀₁	1.88×10²	4.28×10³	1.87×10⁴
	A₀₂	2.81×10¹	7.48×10¹	2.00×10³
	A₁₀	1.10×10⁵	6.50×10²	5.79×10⁴
	A₁₁	4.13×10⁶	9.13×10⁴	1.32×10⁷
	A₁₂	1.32×10⁴	1.57×10⁴	1.45×10⁵
${R_{\upsilon '\upsilon ''}}$	R₀₀	0.99996	0.9484	0.9985
	R₀₁	3.7×10^–5	0.0506	0.0014
	R₀₂	5.6×10^–6	0.0009	0.0001
	R₁₀	0.02592	0.0060	0.0043
	R₁₁	0.9707	0.8394	0.9836
	R₁₂	0.0031	0.1446	0.0108

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map

[1]	Shuman E S, Barry J F, DeMille D 2010 Nature 467 820 Google Scholar
[2]	Hummon M T, Yeo M, Stuhl B K, Collopy A L, Xia Y, Ye J 2013 Phys. Rev. Lett. 110 143001 Google Scholar
[3]	Zhelyazkova V, Cournol A, Wall T E, Matsushima A, Hudson J J, Hinds E A, Tarbutt M R, Sauer B E 2014 Phys. Rev. A 89 053416 Google Scholar
[4]	Gao Y, Gao T 2014 Phys. Rev. A 90 052506 Google Scholar
[5]	You Y, Yang C L, Wang M S, Ma X G, Liu W W 2015 Phys. Rev. A 92 032502 Google Scholar
[6]	Cui J, Xu J G, Qi J X, Dou G, Zhang Y G 2018 Chin. Phys. B 27 103101 Google Scholar
[7]	Wan M J, Yuan D, Jin C G, Wang F H, Yang Y J, Yu Y, Shao J X 2016 J. Chem. Phys. 145 024309 Google Scholar
[8]	张云光, 张华, 窦戈, 徐建刚 2017 66 233101 Google Scholar Zhang Y G, Zhang H, Dou G, Xu J G 2017 Acta Phys. Sin. 66 233101 Google Scholar
[9]	Xu L, Wei W, Xia Y, Deng L Z, Yin J P 2017 Chin. Phys. B 26 033702 Google Scholar
[10]	Yzombard P, Hamamda M, Gerber S, Doser M, Comparat D 2015 Phys. Rev. Lett. 114 213001 Google Scholar
[11]	Zhang Q Q, Yang C L, Wang M S, Ma X G, Liu W W 2017 Spectrochim. Acta. Part A 185 365 Google Scholar
[12]	Zhang Q Q, Yang C L, Wang M S, Ma X G, Liu W W 2017 Spectrochim. Acta. Part A 182 130 Google Scholar
[13]	Zeid I, Abdallah R A, El Kork N, Korek M 2020 Spectrochim. Acta. Part A 224 117461 Google Scholar
[14]	Wan M J, Huang D H, Yu Y, Zhang Y G 2017 Phys. Chem. Chem. Phys. 19 27360 Google Scholar
[15]	万明杰, 李松, 金成国, 罗华锋 2019 68 063103 Google Scholar Wan M J, Li S, Jin C G, Luo H F 2019 Acta. Phys. Sin. 68 063103 Google Scholar
[16]	Deng B L, Wan M J, Zhao X F, Tang K, Zhang X Q 2020 Spectrochim. Acta. Part A 227 117684 Google Scholar
[17]	Stoneman R C, Larson D J 1987 Phys. Rev. A 35 2928 Google Scholar
[18]	Brown J M, Fackerell A D 1982 Physica. Scripta. 25 351 Google Scholar
[19]	Balasubramanian K, Liao M Z, Han M 1987 Chem. Phys. Lett. 139 551 Google Scholar
[20]	Binning Jr R C, Curtiss L A 1990 J. Chem. Phys. 92 1860 Google Scholar
[21]	Werner H J, Knowles P J, Knizia G, et al. 2010 MOLPRO, a Package of ab initio Programs (version 2010.1)
[22]	Knowles P J, Werner H J 1985 J. Chem. Phys. 82 5053 Google Scholar
[23]	Werner H J, Meyer W 1980 J. Chem. Phys. 73 2342 Google Scholar
[24]	Werner H J, Knowles P J 1988 J. Chem. Phys. 89 5803 Google Scholar
[25]	Knowles P J, Werner H J 1988 Chem. Phys. Lett. 145 514 Google Scholar
[26]	Laughoff S R, Davidson E R 1974 Int. J Quantum. Chem. 8 61 Google Scholar
[27]	Douglas N, Kroll N M 1974 Ann. Phys. 82 89 Google Scholar
[28]	Hess B A 1986 Phys. Rev. A 33 3742 Google Scholar
[29]	Berning A, Schweizer M, Werner H J, Knowles P J, Palmieri P 2000 Mol. Phys. 98 1823 Google Scholar
[30]	DeYonker N J, Peterson K A, Wilson A K 2007 J. Phys Chem A 111 11383 Google Scholar
[31]	Dunning Jr T H 1989 J. Chem. Phys. 90 1007 Google Scholar
[32]	Le Roy R J 2007 LEVEL 8.0: a Computer Program for Solving the Radial Schröinger Equation for Bound and Quasibound Levels (Waterloo: University of Waterloo) Chemical Physics Research Report CP-663
[33]	Huber K, Herzberg G 1979 Molecular Spectra and Molecular Structure Vol. 4. Constants of Diatomic Molecules (New York: Van Nostrand Reinhold) p586
[34]	Moore C E 1971 Atomic Energy Levels (Vol. 1) (Washington, DC: US Govt Printing Office) pp2, 150
[35]	Lykke K R, Murray K K, Lineberger W C 1991 Rhys. Rev. A 43 6104 Google Scholar
[36]	Hotop H, Lineberger W C 1985 J. Phys. Chem. Ref. Data 14 731 Google Scholar
[37]	Lane I C 2015 Phys. Rev. A 92 022511 Google Scholar
[38]	You Y, Yang C L, Zhang Q Q, Wang M S, Ma X G, Wang W W 2016 Phys. Chem. Chem. Phys. 18 19838 Google Scholar

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考虑自旋-轨道耦合效应下SeH^–阴离子的光谱和跃迁性质

Spectroscopic and transition properties of SeH^– anion including spin-orbit coupling

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宜宾学院理学部, 宜宾　644007

通信作者: 黄多辉, hdhzhy912@163.com

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Faculty of Science, Yibin University, Yibin 644007, China

Corresponding author: Huang Duo-Hui, hdhzhy912@163.com

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考虑自旋-轨道耦合效应下SeH–阴离子的光谱和跃迁性质

Spectroscopic and transition properties of SeH– anion including spin-orbit coupling

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Abstract

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宜宾学院理学部, 宜宾 644007

通信作者: 黄多辉, hdhzhy912@163.com

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Faculty of Science, Yibin University, Yibin 644007, China

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考虑自旋-轨道耦合效应下SeH^–阴离子的光谱和跃迁性质

Spectroscopic and transition properties of SeH^– anion including spin-orbit coupling

宜宾学院理学部, 宜宾　644007