<b><i>Ab initio</i></b>potential energy curve for the helium atom pair and thermophysical properties of the dilute helium gas. II. Thermophysical standard values for low-density helium

Bich, Eckard; Hellmann, Robert; Vogel, E.

doi:10.1080/00268970701744584

Cited by 117 publications

(102 citation statements)

References 72 publications

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“…The most accurate, zero-pressure values of the thermal conductivity of helium are those calculated ab initio from quantum mechanics and statistical mechanics. [17,18]. In the limit of zero density at T TPW , the most accurate value of the thermal conductivity of argon λ Ar is obtained by combining the calculated value of the Prandtl number Pr ≡C p η/λ , the calculated value of the viscosity of helium η He , and the measurements by May et al of the ratio η Ar /η He ≡ (viscosity of argon)/(viscosity of helium).…”

Section: Thermoacoustic Boundary Layermentioning

confidence: 99%

Optimizing acoustic measurements of the Boltzmann constant

Moldover

2009

Comptes Rendus. Physique

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We review the progress in acoustic metrology of gases that has occurred since the 1988 measurement of the universal gas constant R using a spherical acoustic resonator. The advances in understanding resonators and in calculating the thermophysical properties of helium ab initio suggest that today one could determine Boltzmann's constant k B from acoustic measurements using either helium or argon with a relative uncertainty less than 10 −6 . RésuméProgrès dans la détermination de la constante de Boltzmann par voie acoustique L'article récapitule les avancées effectuées en métrologie acoustique dans les gaz depuis la mesure de la constante universelle des gaz R effectuée en 1988 en utilisant un résonateur acoustique sphérique. Des progrès substantiels ont été réalisés, tant pour mieux comprendre le fonctionnement des résonateurs acoustiques que pour calculer ab initio, avec une fiabilité accrue, les caractéristiques thermo-physiques de l'hélium. Ils permettent d'envisager désormais une détermination de la constante de Boltzmann k B par voie acoustique avec une incertitude relative meilleure que 10 -6 , en utilisant soit l'argon, soit l'hélium.________________________________ 1. Introduction.

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Section: Thermoacoustic Boundary Layermentioning

confidence: 99%

Optimizing acoustic measurements of the Boltzmann constant

Moldover

2009

Comptes Rendus. Physique

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“…The resulting thermophysical properties [3,4] were found to be more accurate than experimental values and can therefore be utilized for calibration of high precision measuring instruments. Since argon is one of the pioneer substances of molecular modeling and a low price alternative for calibration issues, a pair potential of high quality is needed.…”

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confidence: 99%

Ab initiopair potential energy curve for the argon atom pair and thermophysical properties of the dilute argon gas. I. Argon–argon interatomic potential and rovibrational spectra

Jäger¹,

Hellmann²,

Bich³

et al. 2009

Molecular Physics

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127

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initio pair potential energy curve for the argon atom pair and thermophysical properties of the dilute argon gas. I. Argon-argon interatomic potential and rovibrational spectra. Molecular Physics, Taylor & Francis, 2009, 107 (20) An argon-argon interatomic potential energy curve was derived from quantum-mechanical ab initio calculations using basis sets of up to d-aug-cc-pV(6+d)Z quality supplemented with bond functions and ab initio methods up to CCSDT(Q). In addition, corrections for relativistic effects were determined. An analytical potential function was fitted to the ab initio values and utilized to compute the rovibrational spectrum. The quality of the interatomic potential function was tested by comparison of the calculated spectrum with experimental ones and those derived from other potentials of the literature. In a following paper the new interatomic potential is used to determine selected thermophysical properties of argon by means of quantum-statistical mechanics and the corresponding kinetic theory considering two-body and three-body interactions.

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“…For the temperature range required to refine the potential curve between 3 and 4Å, that is, below 5 K, the reference of Becker et al [17] presents 11 values. However, the quality of these data has been questioned [18] due to the use of an old reference value for equipment calibration, resulting in a positive deviation of approximately 5 % as estimated by Bich and Vogel. [18] To generate the necessary data of viscosity coefficients, the equation…”

Section: Resultsmentioning

confidence: 99%

“…However, the quality of these data has been questioned [18] due to the use of an old reference value for equipment calibration, resulting in a positive deviation of approximately 5 % as estimated by Bich and Vogel. [18] To generate the necessary data of viscosity coefficients, the equation…”

Section: Resultsmentioning

confidence: 99%

Accurate potential energy curve for helium dimer retrieved from viscosity coefficient data at very low temperatures

Costa

Lemes

Braga

2017

Physica A: Statistical Mechanics and its Applications

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The long range potential of helium-helium interaction, which requires accurate ab initio calculation, due to the small value of the potential depth, approximately 11 K (9.5 × 10 −4 eV = 0.091 kJ/mol) at 2.96Å, will be obtained in this study by an alternative technique. This work presents a robust and consistent procedure that provides the long range potential directly from experimental data. However, it is difficult to obtain experimental data containing information regarding such a small potential depth. Thereby, sensitivity analysis will be used to circumvent this difficulty, from which viscosity data at lower temperatures (< 5 K) were chosen as appropriate data to be used to retrieve the potential function between 3 and 4Å. The linear relationship between the potential energy function and the viscosity coefficient will be established under quantum assumptions and the Bose-Einstein statistic. The use of quantum theory is essential, since the temperatures are below 5 K. The potential obtained in this study describes the viscosity with an average error of 1.68 % that is less than the experimental error (5 %), with the results being similar to those obtained for recent ab initio potentials.

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Ab initiopotential energy curve for the helium atom pair and thermophysical properties of the dilute helium gas. II. Thermophysical standard values for low-density helium

Cited by 117 publications

References 72 publications

Optimizing acoustic measurements of the Boltzmann constant

Optimizing acoustic measurements of the Boltzmann constant

Ab initiopair potential energy curve for the argon atom pair and thermophysical properties of the dilute argon gas. I. Argon–argon interatomic potential and rovibrational spectra

Accurate potential energy curve for helium dimer retrieved from viscosity coefficient data at very low temperatures

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