Analysis of Gaseous Flows in Minichannels by Molecular Tagging Velocimetry

Samouda, F.; Barrot-Lattes, Christine; Colin, Stéphane; Baldas, Lucien; Laurien, Nicolas

doi:10.1115/icnmm2012-73125

ASME 2012 10th International Conference on Nanochannels, Microchannels, and Minichannels 2012

DOI: 10.1115/icnmm2012-73125

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Analysis of Gaseous Flows in Minichannels by Molecular Tagging Velocimetry

F. Samouda

Christine Barrot-Lattes

Stéphane Colin

et al.

Abstract: The Molecular Tagging Velocimetry (MTV) technique has been widely used for analyzing velocity fields in liquid mini- and microflows. Concerning gaseous flows, only few works describe the implementation of MTV at millimetric scale, and these studies are limited to the analysis of external flows, such as jet flows. The goal of the present work is to develop this technique for the analysis of internal gas flows in minichannels. It is a first step toward the visualization of velocity profiles in rarefied condition… Show more

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“…On the other hand, the first attempts to measure gas flows velocities by MTV inside devices with millimetric or sub-millimetric dimensions are quite recent and the techniques were based on MTV by direct phosphorescence using acetone as tracer molecule [44,55,56] or on MTV by photoproduct fluorescence using nitric oxide as tracer molecule [57]. These few preliminary measurements have been made in rectangular channels using one dimensional molecular tagging velocimetry (1D-MTV); in this case a single line or a series of parallel lines are tagged perpendicularly to the flow direction ( Fig.…”

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

Mohand

Frezzotti

Brandner

et al. 2017

Experimental Thermal and Fluid Science

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Molecular tagging velocimetry is a little-intrusive technique based on the properties of specific molecules able to emit luminescence once properly excited. Several variants of this technique have been successfully developed for analyzing external gas flows or internal gas flows in large systems. There is, however, very few experimental data on molecular tagging velocimetry for gas flows in mini or microsystems, and these data are strongly affected by the molecular diffusion of the tracer molecules. In the present paper, it is demonstrated that the velocity field in gas microflows cannot be directly deduced from the measured displacement field without taking into account Taylor dispersion effects. For that purpose, the benchmark case of a Poiseuille gas flow through a rectangular channel 960 µm in depth is experimentally investigated by micro molecular tagging velocimetry using acetone vapor as a molecular tracer. An appropriate reconstruction method based on the advection diffusion equation is used to process the data and to correctly extract the velocity profiles. The comparison of measured velocities with flowrate data and with theoretical velocity profiles shows a good agreement, whereas when the reconstruction method is not implemented, the extracted velocity field exhibits qualitative and quantitative anomalies, such as a non-physical slip at the walls. The robustness of the reconstruction method is demonstrated on flows with light and heavy molecular species, namely helium and argon, at atmospheric as well as at 2 lower pressure conditions, for which diffusion effects are stronger. The obtained results represent an encouraging step for future analysis of rarefied gas microflows.

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

Mohand

Frezzotti

Brandner

et al. 2017

Experimental Thermal and Fluid Science

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Micro molecular tagging velocimetry for analysis of gas flows in mini and micro systems

et al. 2013

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Role of diffusion on molecular tagging velocimetry technique for rarefied gas flow analysis

Frezzotti

Mohand

Barrot-Lattes

et al. 2015

Microfluid Nanofluid

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The molecular tagging velocimetry (MTV) is a well-suited technique for velocity field measurement in gas flows. Typically, a line is tagged by a laser beam within the gas flow seeded with light emitting acetone molecules. Positions of the luminescent molecules are then observed at successive times and the velocity field is deduced from the analysis of the tagged line displacement and deformation. However, the displacement evolution is expected to be affected by molecular diffusion, when the gas is rarefied. Therefore, there is no direct and simple relationship between the velocity field and the measured displacement of the initial tagged line. This paper addresses the study of tracer molecules diffusion through a background gas flowing in a channel delimited by planar walls. Tracer and background species are supposed to be governed by a system of coupled Boltzmann equations, numerically solved by the direct simulation Monte Carlo (DSMC) method. Simulations confirm that the diffusion of tracer species becomes significant as the degree of rarefaction of the gas flow increases. It is shown that a simple advection–diffusion equation provides an accurate description of tracer molecules behavior, in spite of the non-equilibrium state of the background gas. A simple reconstruction algorithm based on the advection–diffusion equation has been developed to obtain the velocity profile from the displacement field. This reconstruction algorithm has been numerically tested on DSMC generated data. Results help estimating an upper bound on the flow rarefaction degree, above which MTV measurements might become problematic

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Analysis of Gaseous Flows in Minichannels by Molecular Tagging Velocimetry

Cited by 3 publications

References 0 publications

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

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

Micro molecular tagging velocimetry for analysis of gas flows in mini and micro systems

Role of diffusion on molecular tagging velocimetry technique for rarefied gas flow analysis

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