Updated determination of the molar gas constant<i>R</i>by acoustic measurements in argon at UVa-CEM

Segovia, José J.; Lozano-Martín, Daniel; Martín, M. Carmen; Chamorro, César R.; Villamañán, Miguel A.; Perez, E.; Izquierdo, C. Garcia; Campo, D. del

doi:10.1088/1681-7575/aa7c47

Cited by 20 publications

(14 citation statements)

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“…In addition, the recent low-uncertainty determinations INRiM-15 [25], PTB-17 [52], NIM/NIST-17 [85], NPL-17 [46], LNE-17 [26], NIM-17 [27], UVa/CEM-17 [29] and NIST-17 [87] are listed in table 3 with uncertainty values in italics. With the DCGT result PTB-17 [52] and the noise result NIM/NIST-17 [85], the second CCT condition [2], demanding an independent method with a relative standard uncertainty below 3 × 10 −6 , is fulfilled.…”

Section: Discussionmentioning

confidence: 99%

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The Boltzmann project

et al. 2018

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The International Committee for Weights and Measures (CIPM), at its meeting in October 2017, followed the recommendation of the Consultative Committee for Units (CCU) on the redefinition of the kilogram, ampere, kelvin and mole. For the redefinition of the kelvin, the Boltzmann constant will be fixed with the numerical value 1.380 649 × 10−23 J K−1. The relative standard uncertainty to be transferred to the thermodynamic temperature value of the triple point of water will be 3.7 × 10−7, corresponding to an uncertainty in temperature of 0.10 mK, sufficiently low for all practical purposes. With the redefinition of the kelvin, the broad research activities of the temperature community on the determination of the Boltzmann constant have been very successfully completed. In the following, a review of the determinations of the Boltzmann constant k, important for the new definition of the kelvin and performed in the last decade, is given.

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Section: Discussionmentioning

confidence: 99%

“…The 2017 measurement by Universidad de Valladolid (UVa) in collaboration with CEM used argon gas in a gold-coated stainless steel, quasi-spherical resonator with a radius of 40 mm [29]. Several features of the measurement were unique within the project [10].…”

Section: Acoustic Gas Thermometermentioning

confidence: 99%

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“…Dilute gas transport properties serve as a basis for predicting transport properties at high pressures and are important for calibrating scientific apparatus and other measurement devices. 1, 2 For example, accurate viscosities are crucial for the calibration of certain low-flow meters for mass spectrometers, 3,4 and precise thermal conductivities at low densities are required for acoustic thermometry, determination of the universal gas constant, 5,6 and were important to recent (and final) measurements of the Boltzmann constant prior to its redefinition. 7 Several experimental methods are available for measuring viscosities accurately under low density conditions, including rotating-body viscometers, [8][9][10] oscillating-disk viscometers [11][12][13][14] and capillary viscometers.…”

Section: Introductionmentioning

confidence: 99%

Wide-Ranging Reference Correlations for Dilute Gas Transport Properties Based onAb InitioCalculations and Viscosity Ratio Measurements

Rowland

Ghafri

May

2020

Journal of Physical and Chemical Reference Data

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Combined use of experimental viscosity ratios together with ab initio calculations for helium have driven significant improvements in the description of dilute gas transport properties. Here we first use improvements made to ab initio helium calculations to update viscosity ratios measured for H2, Ar, CH4, and Xe by May et al. in 2007 over the temperature range (200 to 400) K, reducing the uncertainties of the data to 0.055%, 0.038%, 0.067%, and 0.084%, respectively. Separately, we extend the technique of combining viscosity ratios with ab initio calculations to develop new reference correlations for the dilute gas viscosity of 10 gases: helium, neon, argon, krypton, xenon, hydrogen, nitrogen, methane, ethane, and propane. This is achieved by combining the ratios of viscosities calculated ab initio at the target temperature and at 298.15 K with experimentally-based reference viscosity values for each gas at 298.15 K. The new reference dilute gas viscosity correlations span temperature ranges from at least (150 to 1200) K, with relative uncertainties between 30% (krypton) to 85% (methane) lower than the original ab initio results. For the noble gases, ab initio calculations for the Prandtl number are used to develop reference correlations for thermal conductivity ranging from at least (100 to 5000) K, with relative uncertainties ranging from 0.04% (argon) to 0.20% (xenon). The new reference correlations are compared with available experimental data at dilute gas conditions. In general, the data agree with the new correlations within the claimed experimental uncertainty.

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“…Both the acoustic cavity and the transducer designs are based on those used by Trusler, Wakeham and Zarari [19][20][21] to measure pure methane and related mixtures. Further details concerning the setup may be found in [22][23][24], while only a brief description is given here. spring of electrical contact, 6. screw, 7. cover plate.…”

Section: Equipment Descriptionmentioning

confidence: 99%

Speed of sound for three binary (CH4 + H2) mixtures from p = (0.5 up to 20) MPa at T = (273.16 to 375) K

Lozano-Martín

Martín

Chamorro

et al. 2020

International Journal of Hydrogen Energy

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Speed of sound is one of the thermodynamic properties that can be measured with least uncertainty and is of great interest in developing equations of state. Moreover, accurate models are needed by the H2 industry to design the transport and storage stages of hydrogen blends in the natural gas network. This research aims to provide accurate data for (CH4 + H2) mixtures of nominal (5, 10, and 50) mol-% of hydrogen, in the p = (0.5 up to 20) MPa pressure range and with temperatures T = (273.16, 300, 325, 350, and 375) K. Using an acoustic spherical resonator, speed of sound was determined with an overall relative expanded (k = 2) uncertainty of 220 parts in 10 6 (0.022 %). Data were compared to reference equations of state for natural gas-like mixtures, such as AGA8-DC92 and GERG-2008.Average absolute deviations below 0.095% and percentage deviations between 0.029% and up to 0.30%, respectively, were obtained. Additionally, results were fitted to the acoustic virial equation of state and adiabatic coefficients, molar isochoric heat capacities and molar isobaric heat capacities as perfect-gas, together with second and third acoustic virial coefficients, and were estimated. Density second virial coefficients were also obtained. KeywordsSpeed of sound; acoustic resonator; methane; hydrogen; heat capacities as perfect gas; virial coefficients R Molar gas constant, J•mol −1 •K −1 1 Component 1 of a binary mixture s Standard deviation 2 Component 2 of a binary mixture T Temperature, K AGA8 -DC92 Calculated from AGA8-DC92 equation of state u Standard uncertainty c Critical parameter U Expanded uncertainty EoS Calculated from an equation of state V Volume, m 3 exp Experimental data Vh Volume of the holes drilled in the transducer backplate, m 3 GERG -2008

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Updated determination of the molar gas constantRby acoustic measurements in argon at UVa-CEM

Cited by 20 publications

References 39 publications

The Boltzmann project

The Boltzmann project

Wide-Ranging Reference Correlations for Dilute Gas Transport Properties Based onAb InitioCalculations and Viscosity Ratio Measurements

Speed of sound for three binary (CH4 + H2) mixtures from p = (0.5 up to 20) MPa at T = (273.16 to 375) K

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