Molecular tagging velocimetry by direct phosphorescence in gas microflows: Correction of Taylor dispersion

Mohand, Hacene Si Hadj; Frezzotti, Aldo; Brandner, Juergen J.; Barrot-Lattes, Christine; Colin, Stéphane

doi:10.1016/j.expthermflusci.2017.01.002

Cited by 12 publications

(10 citation statements)

References 68 publications

(74 reference statements)

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“…However, the image data revealed that these effects are negligible, and the Gaussian function is still representative of the light distribution in the gas flow direction. As it has been done in previous works [12,14,20], the Gaussian fitting applied to each horizontal line of pixels at any position y = y j is…”

Section: Mtv Image Post-processingmentioning

confidence: 99%

“…In this section, the MTV technique was applied to acetone-seeded argon flows in non-rarefied conditions. The previous works of Samouda et al [12] and Si-Hadj Mohand et al [14] already demonstrated the successful application of MTV for velocity measurements in channel gas flow in non-rarefied conditions by using as a tracer acetone vapor excited at 266 nm. Si Hadj Mohand et al were not able to apply MTV for pressures lower than about 42 kPa because of the low signal intensity due to the limited phosphorescence quantum yield of acetone excited at 266 nm.…”

Section: Mtv Measurements Of Channel Gas Flows In Non-rarefied Conditmentioning

confidence: 99%

“…Later on, the method was proven to be valid also in the case of physical MTV experiments in confined non-rarefied flows. The experiments were performed in a millimetric channel at atmospheric and subatmospheric pressures down to a minimum average pressure of 42 kPa [14]. At this pressure level in a 1-mm deep channel, the flow was still in the continuum regime.…”

Section: Introductionmentioning

confidence: 99%

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Velocity Measurements in Channel Gas Flows in the Slip Regime by means of Molecular Tagging Velocimetry

et al. 2020

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Direct measurements of the slip velocity in rarefied gas flows produced by local thermodynamic non-equilibrium at the wall represent crucial information for the validation of existing theoretical and numerical models. In this work, molecular tagging velocimetry (MTV) by direct phosphorescence is applied to argon and helium flows at low pressures in a 1-mm deep channel. MTV has provided accurate measurements of the molecular displacement of the gas at average pressures of the order of 1 kPa. To the best of our knowledge, this work reports the very first flow visualizations of a gas in a confined domain and in the slip flow regime, with Knudsen numbers up to 0.014. MTV is cross-validated with mass flowrate measurements by the constant volume technique. The two diagnostic methods are applied simultaneously, and the measurements in terms of average velocity at the test section are in good agreement. Moreover, preliminary results of the slip velocity at the wall are computed from the MTV data by means of a reconstruction method.

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Section: Mtv Image Post-processingmentioning

confidence: 99%

Section: Mtv Measurements Of Channel Gas Flows In Non-rarefied Conditmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Velocity Measurements in Channel Gas Flows in the Slip Regime by means of Molecular Tagging Velocimetry

et al. 2020

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“…1D-MTV by direct phosphorescence has already been applied to non-rarefied external supersonic or hypersonic turbulent gas flows [23,24], to rarefied supersonic jets [25] and to non-rarefied gas flows in millimetric channels [26,27]. However, some difficulties have prevented until now the successful application of this technique to confined rarefied gas flows.…”

Section: Introductionmentioning

confidence: 99%

“…A reconstruction method of the velocity profile from the displacement profile was developed and validated with numerical experiments. Si Hadj Mohand et al [27] successfully applied this reconstruction method on MTV data in a millimetric channel and correctly extracted the velocity profile at atmospheric and sub-atmospheric pressures down to a minimum average pressure of 50 kPa. At this pressure level in a 1-mm deep channel, the flow is still in a nonrarefied regime.…”

Section: Introductionmentioning

confidence: 99%

Molecular tagging velocimetry for confined rarefied gas flows: Phosphorescence emission measurements at low pressure

Fratantonio

Rojas-Cárdenas

Mohand

et al. 2018

Experimental Thermal and Fluid Science

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Rarefied gas flows have a central role in microfluidic devices for many applications in various scientific fields. Local thermodynamic non-equilibrium at the wall-gas interface produces macroscopic effects, one of which is a velocity slip between the gas flow and the solid surface. Local experimental data able to shed light on this physical phenomenon are very limited in the literature. The molecular tagging velocimetry (MTV) could be a suitable technique for measuring velocity fields in gas micro flows. However, the implementation of this technique in the case of confined and rarefied gas flows is a difficult task: the reduced number of molecules in the system, which induces high diffusion, and the low concentration of the molecular tracer both drastically reduce the intensity and the duration of the exploitable signal for carrying out the velocity measures. This work demonstrates that the application of the 1D-MTV by direct phosphorescence to gas flows in the slip flow regime and in a rectangular long channel is, actually, possible. New experimental data on phosphorescence emission of acetone and diacetyl vapors at low pressures are presented. An analysis of the optimal excitation wavelength is carried out to maximize the intensity and the lifetime of the tracer emission. The experimental results demonstrate that a little concentration of about 5-10 % of acetone vapor excited at 310 nm or of diacetyl vapor excited at 410 nm in a helium mixture at pressures on the order of 1 kPa provides an intense and durable luminescent signal. In a 1-mm deep channel, a gas flow characterized by these thermodynamic conditions is in the slip flow regime. Moreover, numerical experiments based on DSMC simulations are carried out to demonstrate that an accurate measurement of the velocity profile in a laminar pressure-driven flow is possible for the rarefied conditions of interest.

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Molecular tagging velocimetry of NH fluorescence in a high-enthalpy rarefied gas flow

Zhang

Yan

et al. 2017

Appl. Phys. B

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Molecular tagging velocimetry by direct phosphorescence in gas microflows: Correction of Taylor dispersion

Cited by 12 publications

References 68 publications

Velocity Measurements in Channel Gas Flows in the Slip Regime by means of Molecular Tagging Velocimetry

Velocity Measurements in Channel Gas Flows in the Slip Regime by means of Molecular Tagging Velocimetry

Molecular tagging velocimetry for confined rarefied gas flows: Phosphorescence emission measurements at low pressure

Molecular tagging velocimetry of NH fluorescence in a high-enthalpy rarefied gas flow

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