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SMM Coronagraph Observations of Particulate Contamination

Published online by Cambridge University Press:  12 April 2016

O.C. St. Cyr
Affiliation:
High Altitude Observatory, National Center for Atmospheric Research1, P.O. Box 3000, Boulder, CO 80307
T. Warner
Affiliation:
High Altitude Observatory, National Center for Atmospheric Research1, P.O. Box 3000, Boulder, CO 80307

Abstract

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Some recent images taken by the white light coronagraph telescope aboard the Solar Maximum Mission (SMM) observatory show bright streaks that are apparently caused by particles associated with the spacecraft. In this report we describe these observations, and we analyze the times of their occurrence. We demonstrate that the sightings occur most often near SMM’s orbital dawn, and we speculate that thermal shock is the mechanism that produces the particles. Although these sightings have not seriously affected the coronagraph’s scientific operations, the unexpected passage of bright material through the field of view of sensitive spaceborne telescopes can lead to data loss or, in some cases, serious detector damage. The topic of space debris has become a significant concern for designers of both manned and unmanned orbiting platforms. The returned samples from the SMM spacecraft and the observations reported here provide a baseline of experience for future orbital platforms that plan long duration missions.

Type
Space Debris
Copyright
Copyright © Astronomical Society of the Pacific 1991

References

Bareiss, L.E., Payton, R.M., and Papazian, H.A. (1986). “Shuttle/Spacelab contamination environment and effects handbook”, NASA Contractor Report 3993.Google Scholar
Hundhausen, A.J. (1987). “The origin and propagation of coronal mass ejections”, Proceedings of the Sixth International Solar Wind Conference, NCAR/TN-306+Proc.Google Scholar
Kessler, D.J. (1985). “Orbital debris issues”, Advances in Space Research, 5, Number 2,3.CrossRefGoogle Scholar
Kessler, D.J., Zook, H.A., Potter, A.E., McKay, D.S., Clanton, U.S., Warren, J.L., Watts, L.A., Schultz, R.A., Schramm, L.S., Wentworth, S.J., and Robinson, G.A. (1985). “Examination of returned Solar Max surfaces for impacting orbital debris and meteoroids”. Proc. Lunar and Planetary Science Conf.,16, 434.Google Scholar
Laurance, M.R., and Brownlee, D.E. (1986) “The flux of meteoroids and orbital space debris striking satellites in low Earth orbit”, Nature, 323. 136.Google Scholar
MacQueen, R.M., Csoeke-Poeckh, A., Hildner, E., House, L.L., Reynolds, R., Stanger, A., TePoel, H., and Wagner, W.J. (1980). “The High Altitude Observatory coronagraph/polarimeter on the Solar Maximum Mission”, Solar Physics, 65,91.CrossRefGoogle Scholar
McGuire, J.P. (1976). “Contamination from Skylab as determined from the solar coronagraph data”, NASA TM X-73353.Google Scholar
Rietmeijer, F.J.M., Schramm, L.S., Barrett, R.A., McKay, D.S., and Zook, H.A. (1986). “An inadvertent capture cell for orbital debris and micrometeorites; the main electronics box thermal blanket of Solar Maximum satellite”, Adv. Space Res. 6, No.7,145.Google Scholar
Shara, M.M., and Johnston, M.D. (1986). “Artificial earth satellite crossing the fields of view of, and colliding with orbiting space telescopes”, PASP, 98, 814.CrossRefGoogle Scholar
Schramm, L.S., McKay, D.S., Zook, H.A., and Robinson, G.A. (1985). “Analysis of micrometeorite material captured by the Solar Max”, Proc. Lunar and Planetary Science Conf., 16, 736.Google Scholar
Schuerman, D.W., Beeson, D.E., and Giovane, F. (1977). “Coronagraphic technique to infer the nature of the Skylab particulate environment”. Applied Optics, 16,1591.Google Scholar
St.Cyr, O.C., Warner, T., Beck, S., and Burkepile, J. (1987). “SMM coronagraph observations of contamination in low Earth orbit”, Eos, 68,378.Google Scholar
Woodgate, B.E., and Maran, S.P. (1986). “The Solar Maximum Mission repair-lessons learned”, Space Station Automation II, SPIE Conference Proc.,729,202.CrossRefGoogle Scholar