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Grewing, M.
1982.
Interstellar Matter, Galaxy, Universe.
Vol. 2c,
Issue. ,
p.
134.
Article contents
Isotopes in Galactic Cosmic Rays
Published online by Cambridge University Press: 14 August 2015
Extract
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The data on isotopic ratios of elements in Galactic Cosmic Rays (GCR) is steadily improving and has recently reached the point where some information can be extracted, which has bearing on the problem of the origin of the cosmic rays. By and large, these data have generally confirmed the similarity between solar-type matter and GCR source, when spallation effects and selective acceleration are taken into account. The silicon and iron isotopic ratios, for instance, are consistent with meteoritic ratios. For iron, this is particularly important since two or perhaps even three different nucleosynthesis mechanisms are required to account for the species 54Fe, 56Fe, 58Fe. For carbon, nitrogen and oxygen the problem is that the spallation corrections are large compared to the solar system ratios but nevertheless the present upper limits are not in contradiction with the solar system ratios.
- Type
- Research Article
- Information
- Symposium - International Astronomical Union , Volume 94: Origin of Cosmic Rays , 1981 , pp. 23 - 30
- Copyright
- Copyright © Reidel 1981
References
Black, D.C., and Pepin, R.O., 1969, Earth Planet Sci. Lett.
6, 395, “Trapped neon in Meteorites II”.Google Scholar
Cassé, M., and Paul, J.A., 1980, Ap. J.
237, 236
“Local gamma rays and cosmic ray acceleration by supersonic stellar winds”.Google Scholar
Clayton, R.N., Onuma, N., and Mayeda, T.K.
1976, “A classification of meteorites, based on oxygen isotopes”
Earth Planet. Sci. Lett.
30, 10
Eberhardt, P.
Google Scholar
Jungck, M.H.A., Meier, F.O., and Neiderer, J.
1979
“Presolar grains in Orgueil: evidence from Neon-E”. Ap. J.
234
L 169.Google Scholar
Garcia-Munoz, M., Simpson, J.A., and Wefel, J.P.
1979a, “The isotopes of neon in the galactic cosmic rays”, Ap. J.
232, L95.Google Scholar
Garcia-Munoz, M., Simpson, J.A., and Wefel, J.P.
1979b, “The isotopic composition of neon and magnesium in the low energy cosmic rays”, Kyoto 16th International Cosmic Ray Conference 0G 7–13.Google Scholar
Geiss, J. and Bochsler, P.
1979, “On the abundances of rare ions in the solar wind”
Proc. 4th Solar Wind Conf. Burghausen Springer Verlag.Google Scholar
Mewaldt, R.A.
1980a, “Space craft measurements of the elemental and isotopic composition of solar energetic particles”, Proceedings of the Conference on the Ancient Sun: Fossil Record in the Earth, Moon and Meteorites.Google Scholar
Mewaldt, M.A., Spalding, J.D., Stone, E.C., and Vogt, R.E.
1980b, “The isotopic composition of galactic cosmic ray iron nuclei”, preprint.Google Scholar
Mewaldt, M.A., Spalding, J.D., Stone, E.C., and Vogt, R.E.
1980a, “High resolution measurements of galactic cosmic-ray Ne, Mg and Si isotopes”, Ap. J.
235, L95.Google Scholar
Reeves, H., 1978, “Supernovae contamination of the early solar system in an OB stellar association or the “Big Bang” theory of the origin of the solar system” in “Tucson Conf. on Protostars and Planets” ed. Gehrels, .Google Scholar
Wiedenbeck, M.E. and Greiner, D.E.
1980, A cosmic Ray age based on the abundance of Be. (Preprint)
Google Scholar
Wills, R.D., Bennett, K., Bignami, G.F., Buccheri, R., Caraveo, P., D'Amico, N., Hermsen, W., Kanbach, G., Lichti, G.G., Masnou, J.O., Mayer-Hasselwander, H.A., Paul, J.A., Sacco, B., Swanenburg, B.N.
1980, Proc. COSPAR Symp on Non Solar Gamma Rays, Bangalore (India), Adv. Sp. Expl.
7, 43.Google Scholar
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