2005
DOI: 10.1016/j.chemphys.2004.10.023
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Theoretical electronic structure including spin–orbit effects of the alkali dimer cation

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Cited by 16 publications
(15 citation statements)
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References 40 publications
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“…When comparing present results for K + 2 with those obtained for Rb + 2 [15] and for Cs + 2 [16] using a similar approach, some trends can be pointed out. Quite a lot of states are found to be purely repulsive for the three cations, their number increases …”
Section: Symmetry (N)supporting
confidence: 62%
See 1 more Smart Citation
“…When comparing present results for K + 2 with those obtained for Rb + 2 [15] and for Cs + 2 [16] using a similar approach, some trends can be pointed out. Quite a lot of states are found to be purely repulsive for the three cations, their number increases …”
Section: Symmetry (N)supporting
confidence: 62%
“…The efficiency of the theoretical approach used here for K + 2 is now well-established in describing accurately such one-activeelectron homonuclear systems [15][16][17]. The present calculations were performed using a pseudopotential method that includes a treatment of spin-orbit coupling.…”
Section: Summary Of the Theoretical Approachmentioning
confidence: 99%
“…where the expressions in round brackets are 3j symbols, 2S+1 L||Q 2(4) || 2S+1 L is the reduced matrix element of the quadrupole (hexadecapole) moment, and α 0 (iω) and α 2 (iω) are the scalar and tensor components of the dynamic electric dipole polarizability at imaginary frequency of the atom in the 2S+1 L state. The electronic structure data, including the potential energy curves for the ground and excited electronic states, transition electric dipole moments, and matrix elements of the spin-orbit coupling have been calculated for several ion-atom systems relevant for ongoing experimental efforts: (Na+Ca) + (Gacesa et al, 2016;Makarov et al, 2003), (Rb+Ba) + (Knecht et al, 2010;Krych et al, 2011), (Li/Na/K/Rb/Cs+Sr) + , (Rb+Ca) + (Belyaev et al, 2012;Tacconi et al, 2011), (Rb+Yb) + (Lamb et al, 2012;McLaughlin et al, 2014;Sayfutyarova et al, 2013), (Li+Yb) + da Silva Jr et al, 2015;Tomza et al, 2015), (Ca/Sr/Ba/Yb+Cr) + (Tomza, 2015), (Li+Be) + (Ghanmi et al, 2017), (Li+Mg) + (ElOualhazi and , (Li+Ca) + (Saito et al, 2017), (Li+Sr) + (Jellali et al, 2016), (Rb+Ca/Sr/Ba/Yb) + (da Silva Jr et al, 2015), (Na/Ka/Rb+Be) + (Ladjimi et al, 2018), (Li+Li) + (Bouchelaghem and Bouledroua, 2014;Bouzouita et al, 2006;Musia l et al, 2015), (Na+Na) + (Berriche, 2013;Bewicz et al, 2017), (K+K) + (Skupin et al, 2017), (Rb+Rb) + (Jraij et al, 2003;Jyothi et al, 2016), (Cs+Cs) + (Jamieson et al, 2009;Jraij et al, 2005), (Li+Na) + (Li et al, 2015;Musia l et al, 2018), (Li+K) + (Berriche et al, 2005;…”
Section: Atomic Ion and Atommentioning
confidence: 99%
“…Spin-orbit couplings (SOCs) have received much attention in recent theoretical studies [1][2][3][4][5][6][7]. The phenomenon of SOC arises from the interaction of the intrinsic magnetic moment of an electron with its orbital angular momentum, which is ubiquitous among a very broad swath of chemistry, physics, biochemistry, and biology.…”
Section: Introductionmentioning
confidence: 99%