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A calculation is made of the rate of diffusion of "tagged" molecules in a pure gas at uniform pressure in a long capillary tube of half-length L and radius a. At pressures for which the mean free path, the result in the limit L reduces to that already obtained by M. Knudsen, the diffusion coefficient D being given by 2av3, where v is the mean molecular speed. For a capillary of finite length the diffusion coefficient is, to first order in aL, smaller than this by a factor 1-3a4L. In the opposite limit of high pressures, for which, the result reduces to the elementary kinetic theory expression for the self diffusion coefficient, D=3. One of the most significant features of the result is that in a long tube the diffusion coefficient drops very rapidly with increasing pressure from its initial value for. Thus the initial slope of D as a function of pressure is given by dDd (a{) }-12va lnLa. It is shown that these results account for the anomalous low pressure minima observed by several investigators who have measured the specific flow G through long capillary tubes as a function of mean pressure p. The failure to observe such minima with porous media, for which effectively L in each pore, is also explained by these results. The formulae obtained here represent a rigorous solution to the long capillary diffusion problem, valid at all pressures and subject only to the limitations of the mean free path type of treatment.
Pollard et al. (Thu,) studied this question.
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