High-resolution emission spectra of MgH and MgD in the 600 to 850 nm wavelength region

Balfour, Walter J.; Lindgren, B.

doi:10.1139/p78-101

Cited by 48 publications

(101 citation statements)

References 4 publications

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“…Details about this procedure are given in a separate publication for the B ′ ← X electronic transition in MgH (Skory et al 2002). In this way, the dissociation energies D 0 0 coincide with the experimental values given by Balfour & Lindgren (1978) for the ground state and by Balfour & Cartwright (1976) for the A 2 Π state. The dissociation energies adopted here are 10,243.26 and and 12,903.71 cm −1 for the X 2 Σ + and A 2 Π of 24 MgH, respectively.…”

Section: Potential Curves and Dipole Transition Momentssupporting

confidence: 87%

“…The spectrum of MgH has been extensively studied in the laboratory for many decades (Balfour & Cartwright 1976;Balfour & Lindgren 1978;Bernath et al 1985;Wallace et al 1999, and references therein) and has received some theoretical attention (Saxon et al 1978;Kirby et al 1979, and references therein). However, modern stellar atmosphere calculations require extensive, and complete, molecular line lists as molecular band absorption is the primary source of line-blanketing in cool stellar atmospheres, particularly M dwarfs.…”

Section: Introductionmentioning

confidence: 99%

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The Molecular Line Opacity of MgH in Cool Stellar Atmospheres

Weck

Schweitzer

Stancil

et al. 2003

ApJ

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A new, complete, theoretical rotational and vibrational line list for the A-X electronic transition in MgH is presented. The list includes transition energies and oscillator strengths for all possible allowed transitions and was computed using the best available theoretical potential energies and dipole transition moment function with the former adjusted to account for experimental data. The A-X line list, as well as new line lists for the B'-X and the X-X (pure rovibrational) transitions, were included in comprehensive stellar atmosphere models for M, L, and T dwarfs and solar-type stars. The resulting spectra, when compared to models lacking MgH, show that MgH provides significant opacity in the visible between 4400 and 5600 Angstrom. Further, comparison of the spectra obtained with the current line list to spectra obtained using the line list constructed by Kurucz (1993) show that the Kurucz list significantly overestimates the opacity due to MgH particularly for the bands near 5150 and 4800 Angstrom with the discrepancy increasing with decreasing effective temperature.Comment: 10 pages, 4 figures, 3 table

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Section: Potential Curves and Dipole Transition Momentssupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

The Molecular Line Opacity of MgH in Cool Stellar Atmospheres

Weck

Schweitzer

Stancil

et al. 2003

ApJ

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“…The energy levels were calculated using molecular constants by Shayesteh et al (2004) and we adopted a dissociation energy of 1.27 eV (Balfour & Lindgren 1978). Oscillator strengths were obtained from transition probabilities given by Weck et al (2003).…”

Section: Atomic and Molecular Datamentioning

confidence: 99%

Magnesium Isotopes in Metal-poor Dwarfs: The Rise of AGB Stars and the Formation Timescale of the Galactic Halo

Meléndez

Cohen

2007

ApJ

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We have determined magnesium isotopic ratios ( 25,26 Mg/Mg) in metal-poor (−2.6 ≤ [Fe/H] ≤ −1.3) halo dwarfs employing high S/N (90-280) high spectral resolution (R = 10 5 ) Keck HIRES spectra. Unlike previous claims of an important contribution from intermediate-mass AGB stars at low metallicities, we find that the rise of the AGB contribution in the Galactic halo did not occur until intermediate metallicities ([Fe/H] −1.5).

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“…This comprehensive analysis led to an experimental value of 1.27͑3͒ eV for the dissociation energy of the X 2 ⌺ ϩ ground state of MgH. 15 Parallel to the experimental work in 1970s, several ab initio calculations were performed for the ground state and the low-lying excited states. 16 -21 A nearly complete set of laboratory references to work prior to 1977 was compiled by Huber and Herzberg.…”

Section: Introductionmentioning

confidence: 99%

Fourier transform infrared emission spectra of MgH and MgD

Shayesteh

Appadoo

Gordon

et al. 2004

The Journal of Chemical Physics

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High resolution Fourier transform infrared emission spectra of MgH and MgD have been recorded. The molecules were generated in an emission source that combines an electrical discharge with a high temperature furnace. Several vibration-rotation bands were observed for all six isotopomers in the X (2)Sigma(+) ground electronic state: v=1-->0 to 4-->3 for (24)MgH, v=1-->0 to 3-->2 for (25)MgH and (26)MgH, v=1-->0 to 5-->4 for (24)MgD, v=1-->0 to 4-->3 for (25)MgD and (26)MgD. The new data were combined with the previous ground state data, obtained from diode laser vibration-rotation measurements and pure rotation spectra, and spectroscopic constants were determined for the v=0 to 4 levels of (24)MgH and the v=0 to 5 levels of (24)MgD. In addition, Dunham constants and Born-Oppenheimer breakdown correction parameters were obtained in a combined fit of the six isotopomers. The equilibrium vibrational constants (omega(e)) for (24)MgH and (24)MgD were found to be 1492.776(7) cm(-1) and 1077.298(5) cm(-1), respectively, while the equilibrium rotational constants (B(e)) are 5.825 523(8) cm(-1) and 3.034 344(4) cm(-1). The associated equilibrium bond distances (r(e)) were determined to be 1.729 721(1) A for (24)MgH and 1.729 157(1) A for (24)MgD.

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High-resolution emission spectra of MgH and MgD in the 600 to 850 nm wavelength region

Cited by 48 publications

References 4 publications

The Molecular Line Opacity of MgH in Cool Stellar Atmospheres

The Molecular Line Opacity of MgH in Cool Stellar Atmospheres

Magnesium Isotopes in Metal-poor Dwarfs: The Rise of AGB Stars and the Formation Timescale of the Galactic Halo

Fourier transform infrared emission spectra of MgH and MgD

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