Potential-Energy Curves for the X 1Σg+, b3Σu+, and C 1Πu States of the Hydrogen Molecule

Kol, W.; Wolniewicz, L.

doi:10.1063/1.1697142

Cited by 1,365 publications

(221 citation statements)

References 17 publications

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“…Accurate interaction energies [3,4] have allowed accurate calculations [5][6][7] of the spin-flip cross sections for the collision of hydrogen atoms; the theoretical results agree well with measured data [8]. On the other hand, the comparison for H-O 2 is considerably less satisfactory; spin-flip-scattering calculations with accurate interaction energies have been recommended [9,10] to help resolve differences in measured data.…”

Section: Introductionsupporting

confidence: 47%

Abinitiopotential-energy surfaces and electron-spin-exchange cross sections for H-O2interactions

1996

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Accurate quartet-and doublet-state potential-energy surfaces for the interaction of a hydrogen atom and an oxygen molecule in'their ground states have been determined from an ab initio calculation using large-basis sets and the internally contracted multireference configuration interaction method. These potential surfaces have been used to calculate the H-O 2 electron-spin-exchange cross section; the square root of the cross section (in a0), not taking into account inelastic effects, can be obtained approximately from the expressions 2.390E-1/6 and 5.266-0.708 logl0(E) at low and high collision energies E (in Eh), respectively. These functional forms, as well as the oscillatory structure of the cross section found at high energies, are expected from the nature of the interaction energy. The mean cross section (the cross section averaged over a Maxwellian velocity distribution) agrees reasonably well with the results of measurements., ,_. / 1 i, /J

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Section: Introductionsupporting

confidence: 47%

Abinitiopotential-energy surfaces and electron-spin-exchange cross sections for H-O2interactions

1996

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“…The He-H pair interaction is shown in figure 1 and the H-H interaction is given by the BornOppenheimer potential of the ground state of H 2 [32]. The ground vibrational level of H 2 has a binding energy of −4.4774 eV.…”

Section: The He-h-h Systemmentioning

confidence: 99%

Calculations of the binding energies of weakly bound He-He-H, He-He-H^-and He-H-H molecules

Lin

1999

J. Phys. B: At. Mol. Opt. Phys.

124

169

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Abstract. We searched for the existence of weakly bound He-He-H, He-He-H − and He-H-H molecules where the binding energies are expected to be of the order of degrees Kelvin. By employing the best empirical interaction between each pair of particles, we solved the Schrödinger equation for the triatomic systems using hyperspherical coordinates in the adiabatic approximation. We found no bound states for 4 He-4 He-1 H, three bound states for 4 He-4 He-1 H − and one bound state for 4 He-1 H-1 H. Bound states for other isotope combinations are also examined.

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“…Broadening of Lyα line by H-H collisions plays a minor role compared to H-H 2 encounters. The potential interactions for H-H configurations were taken from Kolos & Wolniewicz (1965) and the transition probability was assumed constant in this case. The main effect of the Lyα quasi-molecular opacity is a reduction of the predicted flux at wavelength smaller than 5000 Å for white dwarfs cooler than T eff ≈ 6000 K.…”

Section: Model Atmospherementioning

confidence: 99%

Evolution and colors of helium-core white dwarf stars with high-metallicity progenitors

Althaus

Panei

Romero

et al. 2009

A&A

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Aims. Motivated by the recent detection of single and binary He-core white dwarfs in metal-rich clusters, we present a full set of evolutionary calculations and colors appropriate to the study of these white dwarfs. The paper is also aimed at investigating whether stable hydrogen burning may constitute a major source of energy for massive He-core white dwarfs resulting from high-metallicity progenitors. Methods. White dwarf sequences are derived by considering the evolutionary history of progenitor stars with supersolar metallicities. We also incorporate a self-consistent, time-dependent treatment of gravitational settling and chemical diffusion, as well as of the residual nuclear burning. Results. We find that the influence of residual nuclear burning during the late stages of white dwarf evolution is strongly dependent on the chemical diffusion at the base of the hydrogen-rich envelope. When no diffusion is considered, residual hydrogen burning strongly influences the advanced stages of white dwarf cooling, introducing evolutionary delays of several Gyr. By contrast, when diffusion is taken into account, the role of residual nuclear burning is strongly mitigated, and the evolution is only dictated by the thermal content stored in the ions. In addition, for all of our sequences, we provide accurate color and magnitudes on the basis of new and improved non-gray model atmospheres that explicitly include Lyα quasi-molecular opacity.

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Potential-Energy Curves for the X 1Σg+, b3Σu+, and C 1Πu States of the Hydrogen Molecule

Cited by 1,365 publications

References 17 publications

Abinitiopotential-energy surfaces and electron-spin-exchange cross sections for H-O2interactions

Abinitiopotential-energy surfaces and electron-spin-exchange cross sections for H-O2interactions

Calculations of the binding energies of weakly bound He-He-H, He-He-H^-and He-H-H molecules

Evolution and colors of helium-core white dwarf stars with high-metallicity progenitors

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Potential-Energy Curves for the X 1Σg+, b3Σu+, and C 1Πu States of the Hydrogen Molecule

Cited by 1,365 publications

References 17 publications

Abinitiopotential-energy surfaces and electron-spin-exchange cross sections for H-O2interactions

Abinitiopotential-energy surfaces and electron-spin-exchange cross sections for H-O2interactions

Calculations of the binding energies of weakly bound He-He-H, He-He-H-and He-H-H molecules

Evolution and colors of helium-core white dwarf stars with high-metallicity progenitors

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Calculations of the binding energies of weakly bound He-He-H, He-He-H^-and He-H-H molecules