The stability of a rigidly rotating column of liquid

L. M. Hocking

doi:10.1112/S0025579300001510

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The stability of a non-rotating column of liquid was discussed by Rayleigh [1] who showed that axisymmetric disturbances of wave-lengths greater than the circumference of the column decreased the surface area and the consequent release of surface energy enabled the disturbance to grow. Rayleigh [2] also considered the effect of viscosity on the same problem and found that for high viscosity the range of stability was unaltered. For disturbances which are the same in all planes perpendicular to the axis of the column, it is clear that any disturbance increases the length of the boundary of a plane section of the column and hence increases the surface energy. Thus the column is stable for these disturbances.

References

1.Rayleigh, Lord, Proc. London Math. Soc., 10 (1878), 4–13.CrossRef Google Scholar

2.Rayleigh, Lord, Phil. Mag., 34 (1892), 145–164.CrossRef Google Scholar

3.Hooking, L. M. and Michael, D. H., Mathematika, 6 (1959), 25–32.CrossRef Google Scholar

4.Goldstein, S. (ed.), Modern developments in fluid dynamics (Oxford, 1938), 115.Google Scholar

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