Thermal diffusion and mixture separation in the acoustic boundary layer

Swift, G. W.; Spoor, P. S.

doi:10.1121/1.427929

Cited by 26 publications

(20 citation statements)

References 11 publications

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“…To emphasize the main properties of the phenomena (strong coupling between temperature and concentration variations inside the boundary layers) the appropriate form of the operator on the left hand side is a "product" of two spatial second order operators, 9 leading to (expression of the complex wavenumbers k hD and k Dh are given in Appendix A)…”

Section: A Solutions For the Temperature Variationmentioning

confidence: 99%

“…17,18 Finally, the diffusion coefficient D, which depends on the gas composition and the temperature and inversly proportional to the static pressure, is determined by interpolating experimental results. 2,19 The thermal diffusion ratio k T , as suggested in recent works, 9,12 is expressed by different functions of x for each gas mixture. For the gas mixtures considered (He-Ar and He-Xe), the component 1 is chosen to be helium.…”

Section: Applicationsmentioning

confidence: 99%

“…9 The acoustic pressure p in a spherical cavity satisfies the propagation equation (16a), in which the dissipative effects in the bulk are expressed in the wavenumber k a [Eq. (16b)], associated to the following boundary condition (out of sound source):…”

Section: A Resonance Properties Of Gas-filled Spherical Cavitymentioning

confidence: 99%

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Acoustic fields in binary gas mixtures: Mutual diffusion effects throughout and beyond the boundary layers

Guianvarc'H

Bruneau

2012

The Journal of the Acoustical Society of America

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The acoustic behavior in thermo-viscous gas mixtures, both in proximity of walls and far from them (outside the boundary layers), involves deviations from the adiabatic and laminar movements in pure gases, which result from the influence of several diffusive fields, namely, shear, entropic, and concentration variation fields (their energy being provided by the acoustic field itself). Owing to the boundary conditions, that are slip condition, isothermal condition and concentration flux vanishing on the walls, a strong coupling between these fields occurs inside the boundary layers while their effects appear to be simple additive processes in the bulk of the medium. Although recent literature on this subject leads to interesting results, opening the way to several new issues [R. Raspet et al., J. Acoust. Soc. Am. 105, 65-73 (1999); R. Raspet et al., J. Acoust. Soc. Am. 112, 1414-1422 (2002); G. W. Swift and P. S. Spoor, J. Acoust. Soc. Am. 106, 1794-1800 (1999); D. A. Geller and G. W. Swift, J. Acoust. Soc. Am. 111, 1675-1684 (2002)], the results available still have limitations because they do not provide complete solutions for the propagative and diffusive fields throughout and beyond the boundary layers. The present work aims at providing these solutions in the whole domains considered. The results allow interpreting analytically the behavior of the fields above mentioned in closed cavities and ducts, and particularly in spherical cavities which are best suited to develop metrological applications.

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Section: A Solutions For the Temperature Variationmentioning

confidence: 99%

Section: Applicationsmentioning

confidence: 99%

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Acoustic fields in binary gas mixtures: Mutual diffusion effects throughout and beyond the boundary layers

Guianvarc'H

Bruneau

2012

The Journal of the Acoustical Society of America

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“…The latter has been investigated recently both experimentally and theoretically by Swift, Spoor, and Geller, [1][2][3] and been shown to be an effective means of separating even isotopes by coupling the diffusion due to thermal gradients created by acoustic waves at boundaries and transport by the acoustic waves. In contrast, barodiffusion, although in existence for several decades, has not been evaluated since the advent of more efficient and powerful transducers, such as those developed for machining, welding, surgery, and various other medical applications.…”

Section: Introductionmentioning

confidence: 96%

Simulation of ultrasonic-driven gas separations

Rector

Greenwood

Ahmed

et al. 2007

The Journal of the Acoustical Society of America

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The separation of components in a gas mixture is important for a wide range of applications. One method for achieving this separation is by passing a traveling acoustic wave through the gas mixture, which creates a flux of the lighter components away from the transducer. A series of simulations was performed to assess the effectiveness of this method for separating a binary mixture of argon and helium using the lattice kinetics method. The energy transport equation was modified to account for adiabatic expansion and compression. The species transport equation was modified to include a barodiffusion term. Simulations were performed on two different scales; detailed acoustic wave simulations to determine the net component flux as a function of local concentration, pressure, etc. and device scale simulations to predict the gas composition as a function of time inside a gas separation cylinder. The method is first validated using data from literature and then applied to mixtures of argon and helium. Results are presented and discussed.

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“…A scientific investigation of this phenomenon can be found in studies conducted in the 80s and 90s of the 20th century. In particular, they are the works of Rott from the 60s and 70s, and Weatley and Swift from the 80s and 90s, and others [1][2][3]6]. The simplest method to induce a thermoacoustic wave is the application of the Rijke tube [8,9].…”

Section: Introductionmentioning

confidence: 99%

Numerical modeling of CO2 separation process

Remiorz¹,

Rulik²,

Dykas³

2013

Archives of Thermodynamics

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Paper presents the results of numerical modelling of a rectangular tube filled with a mixture of air and CO2 by means of the induced standing wave. Assumed frequency inducing the acoustic waves corresponds to the frequency of the thermoacoustic engine. In order to reduce the computational time the engine has been replaced by the mechanical system consisting of a piston. This paper includes the results of model studies of an acoustic tube filled with a mixture of air and CO2 in which a standing wave was induced.

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Thermal diffusion and mixture separation in the acoustic boundary layer

Cited by 26 publications

References 11 publications

Acoustic fields in binary gas mixtures: Mutual diffusion effects throughout and beyond the boundary layers

Acoustic fields in binary gas mixtures: Mutual diffusion effects throughout and beyond the boundary layers

Simulation of ultrasonic-driven gas separations

Numerical modeling of CO2 separation process

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