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Spectral Analysis of Four Meteors

Published online by Cambridge University Press:  12 April 2016

Gale A. Harvey
Gale A. Harvey*
Affiliation:
Langley Research Center, NASAHampton, Virginia

Abstract

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Four meteor spectra from the NASA LRC Faint Meteor Spectra Patrol are analyzed for chemical composition and radiative processes. The chemical compositions of the Taurid, Geminid, and Perseid meteors were found to be similar to that of a typical stony meteorite. The chemical composition of the sporadic meteor was found to be similar to that of a nickel-iron meteorite. The radiation from optical meteors (+ 1 to —10 absolute photographic magnitude) was found to be similar to that of a low-temperature gas, except that strong, anomalous ionic radiation is superposed on the neutral radiation in bright (< — 3 mag), fast meteors.

Type
Research Article
Information
International Astronomical Union Colloquium , Volume 13: Evolutionary and Physical Properties of Meteoroids , June 1971 , pp. 103 - 129
Copyright
Copyright © NASA 1971

References

Ayers, W. G., Mcceosky, R. E., and Shao, C.-Y., 1970. Photographic observations of 10 artificial meteors, Smithson. Astrophys. Obs. Spec. Rept. No. 317, 110.Google Scholar
Ceplecha, Z., 1964. Study of a bright meteor flare by means of emission curve of growth, Bull. Astron. Inst. Czech., 15, 102112.Google Scholar
Ceplecha, Z., 1965. Complete data on bright meteor 32281, Bull. Astron. Inst. Czech., 16, 88101.Google Scholar
Ceplecha, Z., 1967. Spectroscopic analysis of iron meteoroid radiation, Bull. Astron. Inst. Czech., 18, 303310.Google Scholar
Cook, A. F., Jacchia, L. G., and McCrosky, R. E., 1963. Luminous efficiency of iron and stone asteroidal meteors, Smithson. Contrib. Astrophys., 7, 209220.Google Scholar
Corliss, C. H., 1962. Ionization in the plasma of a copper arc, J. Res. Nat. Bur. Standards, 66A, 169175.Google Scholar
Corliss, C. H., and Bozman, W. R., 1962. Experimental transition probabilities for spectral lines of seventy elements, NBS Monograph 53, U.S. Dept. of Commerce, Washington.Google Scholar
D’Aiutolo, C. T., Kinard, W. H., and Nauman, R. J., 1967. Recent NASA meteoroid penetration results from satellites, Smithson. Contrib. Astrophys., 11, 239251.Google Scholar
Elterman, L., 1964. Atmospheric attenuation model, 1964, in the ultraviolet, visible, and infrared regions for altitudes to 50 km, U.S. Air Force Environ. Res. Papers No. 46 (AFCRL-64-740), Sept. 1964, 140.Google Scholar
Griem, H. R., 1964. Plasma Spectroscopy, McGraw-Hill Book Co., New York, 580 pp.Google Scholar
Grygar, J., Kohoutek, L., and Plavcová, Z., 1968. Simultaneous radar and optical observation of meteors at Ondřejov in 1962, in Physics and Dynamics of Meteors, edited by Kresák, L. and Millman, P. M., D. Reidel Publ. Co., Dordrecht, Holland, 6369.Google Scholar
Halliday, I., 1961. A study of spectral line identifications in Perseid meteor spectra, Publ. Dominion Obs., 25, 116.Google Scholar
Halliday, I., 1969. A study of ultraviolet meteor spectra, Publ. Dominion Obs., 25, 315322.Google Scholar
Harvey, G. A., 1967a. Photometry of spectrograms of three artificial meteors, NASA Tech. Note D-3930, 130.Google Scholar
Harvey, G. A., 1967b. A method of slitless absolute spectral photometry, NASA Tech. Note D-3765, 120.Google Scholar
Harvey, G. A., 1970. Spectra of faint optical meteors, unpublished.Google Scholar
Harvey, G. A., 1971a. The NASA LRC faint meteor spectra patrol, NASA Tech. Note D-6298, 125.Google Scholar
Harvey, G. A., 1971b. The calcium H- and X-line anomaly in meteor spectra, Astrophys. J., 165, 669671.Google Scholar
Hoffman, H. S., 1971. Ionic spectra of meteors, Astrophys. J., 163, 393403.Google Scholar
Hoffman, H. S., and Longmire, M. S., 1968. Meteor ion spectra, Nature, 218, 858859.Google Scholar
Jacchia, L. G., Verniani, F., and Briggs, E., 1967. An analysis of the atmospheric trajectories of 413 precisely reduced photographic meteors, Smithson. Contrib. Astrophys., 10, 1139.Google Scholar
Kittel, C., 1958. Elementary Statistical Physics, J. Wiley and Sons, New York, 228 pp.Google Scholar
Lindblad, B. A., 1963. The relation between visual magnitudes and the durations of radar echoes, Smithson. Contrib. Astrophys., 7, 2739.Google Scholar
Millman, P. M., 1932. An analysis of meteor spectra, Harvard College Obs. Ann., 82, 113146.Google Scholar
Millman, P. M., 1935. An analysis of meteor spectra: second paper, Harvard College Obs. Ann., 82, 149177.Google Scholar
Millman, P. M., 1967. Some characteristics of the major meteor showers, Smithson. Contrib. Astrophys., 11, 105108.Google Scholar
Moore, C. E., 1945. A multiplet table of astrophysical interest, Contrib. Princeton Univ. Obs, No. 20.Google Scholar
Rajchl, J., 1963. A short note on meteor spectra with low dispersion, Smithson. Contrib. Astrophys., 7, 155156.Google Scholar