Composition Dependence of the Thermal-Diffusion Factor of a Dusty Gas

Annis, B. K.; Malinauskas, A.P.; Yun, K. S.

doi:10.1063/1.1673248

The Journal of Chemical Physics

1970

DOI: 10.1063/1.1673248

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Composition Dependence of the Thermal-Diffusion Factor of a Dusty Gas

B. K. Annis

A.P. Malinauskas

K. S. Yun

Abstract: The composition dependence of the thermal-diffusion factor αT of a dust–gas mixture is derived. In the case of monatomic gas, (αT)−1 is shown to vary linearly with mole fraction, but nonlinear contributions arise in the case of a polyatomic gas as a result of inelastic gas–gas collisions. Application of the result to a description of thermal transpiration in terms of the “dusty-gas” model yields a correction to the previously derived equation for thermal transpiration and may have a significant effect on the d… Show more

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Cited by 10 publications

References 26 publications

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Thermal Transpiration in a Dissociating Gas

Wright

1975

Ber Bunsenges Phys Chem

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By use of the dusty‐gas model, an analysis is given of the gradient of pressure set up in the steady state in a dissociating gas in local chemical equilibrium in a gradient of temperature in a porous medium (or in a capillary tube). For a dissociating gas, though not for an isomerising gas, the gradient of pressure thereby induced can be appreciably greater than for a non‐reacting gas (though the enhancement is less marked than the corresponding enhancement of the thermal conductivity). The enhancement remains appreciable even for a gas in which there is only a small proportion of the associated species; and for a porous medium with very small pores the steady state could in consequence be one with (p−1 δp/δz)/(T−1 δT/δz) detectably greater than the conventional 0.5000. It is shown in passing that a result previously established for a dusty gas at uniform temperature, that the Stefan‐Maxwell equations for diffusion can be compounded with relevant equations for viscous contributions to the resultant fluxes, to give a set of equations of the unaugmented Stefan‐Maxwell form but with modified values for coefficients appearing in them, also holds for a dusty gas in a gradient of temperature.

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Thermal Transpiration in a Dissociating Gas

Wright

1975

Ber Bunsenges Phys Chem

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Theory of drag on neutral or charged spherical aerosol particles

Annis

Malinauskas

Mason

1972

Journal of Aerosol Science

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The size-mobility relationship of ions, aerosols, and other charged particle matter.

Larriba-Andaluz

Carbone

2021

Journal of Aerosol Science

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Composition Dependence of the Thermal-Diffusion Factor of a Dusty Gas

Cited by 10 publications

References 26 publications

Thermal Transpiration in a Dissociating Gas

Thermal Transpiration in a Dissociating Gas

Theory of drag on neutral or charged spherical aerosol particles

The size-mobility relationship of ions, aerosols, and other charged particle matter.

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