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Accumulation of Chondrules on Asteroids

Published online by Cambridge University Press:  12 April 2016

Fred L. Whipple
Fred L. Whipple*
Affiliation:
Smithsonian Astrophysical Observatory and Harvard College Observatory

Abstract

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It is suggested that aerodynamic forces played a significant role in the selective accumulation of chondrules on asteroids moving with respect to the gas in a primeval solar nebula. Particles smaller than millimeter chondrules would sweep by an asteroid moving in a critical velocity range, whereas larger particles could be accumulated by impact. Theory and calculation cover the case of subsonic velocity and asteroidal diameter up to 50 km for a nebula density up to 10-6 g/cm3, or higher for smaller asteroids.

Type
Part II-Origin of Asteroids Interrelations with Comets, Meteorites, and Meteors
Information
International Astronomical Union Colloquium , Volume 12: Physical Studies of Minor Planets , 1971 , pp. 251 - 256
Copyright
Copyright © NASA 1971

References

Cameron, A.G.W. 1962, The Formation of the Sun and Planets. Icarus 1, 1374.Google Scholar
Eucken, A.T. 1944, Über den Zustand des Erdinnern. Naturwiss. 32, 112121.CrossRefGoogle Scholar
Fuchs, N.A. 1964, The Mechanics of Aerosols, ch. 4. Macmillan Co. New York.Google Scholar
Hayashi, C., Jugaku, J., and Nishida, M. 1960, Models of Massive Stars in Helium-Burning Stage. Astrophys. J. 131, 241243.Google Scholar
Kennard, E.H. 1938, Kinetic Theory of Gases, p. 310. McGraw-Hill Book Co., Inc. New York.Google Scholar
Langmuir, I., and Blodgett, K.B. 1945, Mathematical Investigation of Water Droplet Trajectories. General Electric Res. Lab. Rept. RL-225. (1948, Meteorol, J. 5, 175.)Google Scholar
Larimer, I.W., and Anders, E. 1967, Chemical Fractionations in Meteorites-II. Abundance Patterns and Their Interpretation. Geochim. Cosmochim. Acta 31, 12391270.CrossRefGoogle Scholar
Probstein, R.F., and Fassio, F. 1969, Dusty Hypersonic Flows. Fluid Mechanics Lab. Pub. 69–2, MIT. Cambridge.Google Scholar
Soo, S.L. 1967, Fluid Dynamics of Multiphase Systems, ch. 5. Blaisdell Pubi. Co. Waltham, Mass.Google Scholar
Taylor, G.I. 1940, Notes on Possible Equipment and Techniques for Experiments on Icing on Aircraft. R & M no. 2024, Aeronautical Res. Comm. London. Google Scholar
Whipple, F.L. 1966, Chondrules: Suggestion Concerning the Origin. Science 153, 5456.Google Scholar
Wood, J.A. 1963, On the Origin of Chondrules and Chondrites. Icarus 2, 152180.CrossRefGoogle Scholar