Hostname: page-component-8448b6f56d-m8qmq Total loading time: 0 Render date: 2024-04-19T19:35:55.223Z Has data issue: false hasContentIssue false
  • English
  • Français

The Volatile Composition of Comets

Published online by Cambridge University Press:  14 August 2015

H. A. Weaver
H. A. Weaver*
Affiliation:
Space Telescope Science Institute, 3700 San Martin Drive, Baltimore, MD 21218, U.S.A.

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Comets may be our best probes of the physical and chemical conditions in the outer regions of the solar nebula during that crucial period when the planets formed. The volatile composition of cometary nuclei, in particular, can be used to decide whether comets are the product of a condensation sequence similar to that invoked to explain the compositions of the planets and asteroids, or if comets are simply agglomerations of interstellar grains which have been insignificantly modified by the events that shaped the other bodies in the solar system. Although cometary nuclei are not generally accessible to observation, observations of cometary comae can illuminate at least some of the mysteries of the nuclei provided one has a detailed knowledge of the excitation conditions in the coma and also has access to basic atomic and molecular data on the many species present in comets. This paper examines the status of our knowledge of the volatile composition of cometary nuclei and discusses how these data are obtained.

Type
Joint Discussions
Information
Highlights of Astronomy , Volume 8: Highlights of Astronomy. As presented at the XXth General Assembly of the IAU, 1988 , 1989 , pp. 387 - 393
Copyright
Copyright © Kluwer 1989

References

1. Mumma, M.J., Weaver, H.A., Larson, H.P., Davis, D.S. and Williams, M. (1986) ‘Detection of water vapor in Halley’s comet’, Science, 232, 15231528.Google Scholar
2. Combes, M., et al. (1986) ‘Infrared sounding of comet Halley from Vega 1’, Nature, 321, 266268.CrossRefGoogle Scholar
3. Larson, H.P., Mumma, M.J., Weaver, H.A. and Davis, D.S. (1986) ‘Velocity-Resolved observations of water in comet Halley’, Ap. J. Lett., 309, L95L99.Google Scholar
4. Weaver, H.A., Mumma, M.J., Larson, H.P. and Davis, D.S. (1986) ‘Post-Perihelion observations of water in comet Halley’, Nature, 324, 441444.Google Scholar
5. Krankowsky, D., et al. (1986) ‘In situ gas and ion measurements at comet Halley’, Nature, 320, 326329.CrossRefGoogle Scholar
6. Prinn, R.G. and Fegley, B. (1988) ‘Solar nebula chemistry: origin of planetary, satellite, and cometary volatiles’, in Atreya, S. Pollack, J., and Matthews, M. (eds.), Origin and Evolution of Planetary and Satellite Atmospheres, University of Arizona Press, in press.Google Scholar
7. Feldman, P.D. and Brune, W.H. (1977) ‘Carbon production in comet West 1975n’, Ap. J. Lett., 2091, L45L48.Google Scholar
8. Feldman, P.D., et al. (1981) ‘IUE Observations of the UV spectrum of comet Bradfield, Nature, 286, 132135.CrossRefGoogle Scholar
9. Woods, T.N., Feldman, P.D., Dymond, K.F. and Sahnow, D.J. (1986) ‘Rocket ultraviolet spectroscopy of comet Halley and abundance of carbon monoxide and carbon’, Nature, 324, 436438.Google Scholar
10. A’Hearn, M.F. and Feldman, P.D. (1980) ‘Carbon in comet Bradfield (1979l)’, Ap. J. Lett., 242, L187L190.Google Scholar
11. Eberhardt, P., et al. (1987) ‘The CO and Nj abundance in comet p/Halley’, Astron. Ap., 187, 481484.Google Scholar
12. Kawara, K., Gregory, B., Yamamoto, T. and Shibai, H. (1988) ‘Infrared spectroscopic observation of methane in comet Halley’, Astron. Ap., in press.Google Scholar
13. Larson, H.P., Weaver, H.A., Mumma, M.J. and Drapatz, S. (1988) ‘Airborne infrared spectroscopy of comet Wilson (1986l) and comparisons with comet Halley’, Ap. J., in press.CrossRefGoogle Scholar
14. Allen, M., et al. (1987) ‘Evidence for methane and ammonia in the coma of comet p/Halley’, Astron. Ap., 187, 502512.Google Scholar
15. Moroz, V.I., et al. (1987) ‘Detection of parent molecules in comet p/Halley from the LKS-Vega experiment’, Astron. Ap., 187, 513518.Google Scholar
16. Altenhoff, W.J., et al. (1983) ‘Radio observations of comet 1983d’, Astron. Ap., 125, L19L22.Google Scholar
17. Wyckoff, S., Tegler, S., Wehinger, P., Spinrad, H. and Belton, M.J.S. (1988) ‘Abundances in comet Halley at the time of the spacecraft encounters’, Ap. J., 325, 927938.CrossRefGoogle Scholar
18. Marconi, M.L. and Mendis, D.A. (1988) ‘On the ammonia abundance in the coma of Halley's comet’, Ap. J., 330, 513517.CrossRefGoogle Scholar
19. A’Hearn, M.F., et al. (1986) ‘Cyanogen jets in comet Halley’, Nature, 324, 649651.CrossRefGoogle Scholar
20. Bockelée-Morvan, D. and Crovisier, J. (1986) ‘Possible parents for the cometary CN radical: photochemistry and excitation conditions’, Astron. Ap., 151, 90100.Google Scholar
21. Schloerb, F.P., Kinzel, W.M., Swade, D.A. and Irvine, W.M. (1987) ‘Observations of HCN in comet p/Halley’, Astron. Ap., 187, 475480.Google ScholarPubMed
22. Weaver, H.A., et al. (1982) ‘IUE observations of faint comets’, Icarus, 47, 449463.CrossRefGoogle Scholar
23. Jackson, W.M., Halpern, J.B., Feldman, P.D. and Rahe, J. (1982) ‘Production of CS and S in comet Bradneld (1979X)’, Astron. Ap., 107, 385389.Google Scholar
24. A’Hearn, M.F., Feldman, P.D., and Schleicher, D.G. (1983) ‘The Discovery of S2 in comet IRAS-Araki-Alcock 1983d’, Ap. J. Lett., 274, L99103.CrossRefGoogle Scholar
25. Azoulay, G. and Festou, M.C. (1985) ‘The abundance of sulfur in comets’, in Lagerkvist, C.-I. Lindblad, B.A. Lundstedt, H. and Rickman, G. (eds.), Comets, Asteroids, and Meteors II, pp. 273276.Google Scholar