Electronic states and spin-forbidden cooling transitions of AlH and AlF

Wells, Nathan; Lane, Ian C.

doi:10.1039/c1cp21313j

Cited by 96 publications

(67 citation statements)

References 66 publications

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“…The calculated ground-state potential agrees perfectly with the accurate ab initio calculations performed by Wells & Lane (2011) for the short-range internuclear distances (R < 12 au). Since the semi-emperical formula (Olson et al 1971) underestimates off-diagonal matrix elements at short distances, the two lowest model potentials are replaced by the ab initio potentials (Wells & Lane 2011), which have the avoided crossing at R = 7.8 au.…”

Section: Inelastic Hydrogen-collision Ratessupporting

confidence: 71%

“…Since the semi-emperical formula (Olson et al 1971) underestimates off-diagonal matrix elements at short distances, the two lowest model potentials are replaced by the ab initio potentials (Wells & Lane 2011), which have the avoided crossing at R = 7.8 au. To the best of our knowledge, no ab initio calculations for higher lying AlH( 1 Σ + ) potentials have been performed 2 , although transitions between higher lying states, including the ionic one, are of the primary interest for astrophysical applications.…”

Section: Inelastic Hydrogen-collision Ratesmentioning

confidence: 99%

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Inelastic aluminium-hydrogen collision data for non-LTE applications in stellar atmospheres

Belyaev

2013

A&A

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Aims. Rate coefficients for inelastic Al + H and Al + + H − collisions are calculated for all transitions between the seven low-lying levels up to and including the ionic state, namely Al(3p, 4s, 3d, 4p, 5s, nd)+H(1s) and Al + + H − . The data are needed for non-LTE applications in stellar atmospheres and are presented for a temperature range of 1000-10 000 K. Methods. The calculations were obtained by means of the recently proposed model approach based on the asymptotic method for electronic molecular structure determination and on the branching probability current method for the nonadiabatic nuclear dynamics. Results. It is shown that the processes with the highest rates are the excitation and de-excitation ones between the Al(3d), Al(4p) and Al(4s) states in collisions with H, as well as the ion-pair formation and the mutual neutralization processes between these states and the ionic state.

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Section: Inelastic Hydrogen-collision Ratessupporting

confidence: 71%

Section: Inelastic Hydrogen-collision Ratesmentioning

confidence: 99%

Inelastic aluminium-hydrogen collision data for non-LTE applications in stellar atmospheres

Belyaev

2013

A&A

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“…Until recently, the laser cooling of molecules to ultracold temperatures was verified from the perspective of experiment [9][10][11]. Transverse laser cooling was applied to beams of SrF [9] and YO [10] molecules, and longitudinal laser cooling was applied to a supersonic beam of CaF molecules [11], From a theoretical point of view, a series of diatomic polar molecules were considered to be potential molecules for laser cooling, such as the alkaline-earth-metal monofluorides (e.g., BeF [12] and RaF [13]), the alkalineearth-metal monohydrides [14] (e.g., BeH, MgH, CaH, SrH, and BaH) and other polar molecules (e.g., CH [15] and A1F [16], etc.). According to previous research work [8], the molecule must meet the following criteria to be a promising laser-cooling candidate.…”

Section: Introductionmentioning

confidence: 99%

Theoretical study of laser cooling of magnesium monofluoride usingab initiomethods

et al. 2015

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A theoretical investigation of the feasibility of laser-cooling the 24M g19F molecule is performed using ab initio calculations. The low-lying electronic states are determined by the multireference configuration-interaction (MRCI) method, where the Davidson modification ( + 0 with the Douglas-Kroll-Hess scalar relativistic correction is also taken into account. The calculated spectroscopic constants are in excellent agreement with the available experimental data. The Franck-Condon factors (FCFs), radiative lifetimes, and radiative widths are verified by calculating the potential energy curves and the transition dipole moment of the A 2n (v') -*• X 2S +(v) transition. Our calculation indicates that the A 2Tl(u' = 0) -> X 2S + (v = 0) transition provides highly diagonally distributed FCFs (/oo = 0.917) and a short radiative lifetime (r = 7.96 ns) for the A 2n(v' = 0) state, which is short enough for rapid laser cooling. The required cooling wavelengths are in the ultraviolet region. A comprehensive scheme demonstrates the possibility of laser-cooling MgF. Moreover, the C 2S + state is confirmed to be a Rydberg state at the MRCI level, which is in line with experimental conjecture.The B 2 n and D 2 £ + states are also reported, but they have not been observed to date.

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“…The atomic data are taken from [46]. The short-range parameters, A ion = 9 a.u., γ ion = 1.7 a.u., A cov = 7 a.u., γ cov = 2.0 a.u., τ = 2.1 a.u., are determined by adjusting the ground adiabatic PEC to the accurate ab initio AlH(X 1 + ) data [47]. The calculated 10 lowest adiabatic PECs, which have the asymptotic limits below or equal to the ionic limit, are shown in Fig.…”

Section: A Simple Modelmentioning

confidence: 99%

“…show PECs for the states which are below the ionic limit, but their avoided crossings with the ionic PECs take place at distances larger than R = 100 a.u. The symbols are the accurate ab initio data [47]. …”

Section: A Simple Modelmentioning

confidence: 99%

Model approach for low-energy inelastic atomic collisions and application to Al+H and Al++H−

Belyaev

2013

Phys. Rev. A

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A model approach is derived for estimates of cross sections and rate coefficients in low-energy inelastic collisions of hydrogen atoms and negative ions with other atoms and positive ions, which are of astrophysical interests. The approach is based on the asymptotic method for electronic molecular structure determination and on the branching probability current method for a nonadiabatic nuclear dynamical treatment. The derived approach is applied to low-energy Al + H and Al + + H − inelastic collisions. It is shown that the processes with the largest values of cross sections and rates are the excitation and de-excitation ones between the Al(3d) and Al(4p) states in collisions with H, as well as the ion-pair formation and the mutual neutralization processes between these states and the ionic state; the second largest cross sections correspond to the similar processes involving the Al(4s) state. The mechanisms of the processes are discussed in detail.

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Electronic states and spin-forbidden cooling transitions of AlH and AlF

Cited by 96 publications

References 66 publications

Inelastic aluminium-hydrogen collision data for non-LTE applications in stellar atmospheres

Inelastic aluminium-hydrogen collision data for non-LTE applications in stellar atmospheres

Theoretical study of laser cooling of magnesium monofluoride usingab initiomethods

Model approach for low-energy inelastic atomic collisions and application to Al+H and Al++H−

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