Impacts on the Hubble Space Telescope Wide Field and Planetary Camera 2: Experimental Simulation of Micrometeoroid Capture

Mark C. Price,Anton T. Kearsley,Penelope J. Wozniakiewicz,John Spratt,Mark J. Burchell,M. J. Cole,P. Anz-Meador,J.-C. Liou,D. K. Ross,J. Opiela,G.W. Grime,R.P. Webb,C. Jeynes,Palitsin. V. V.,Julien L. Colaux,T. Griffin,L. Gerlach

Impacts on the Hubble Space Telescope Wide Field and Planetary Camera 2: Experimental Simulation of Micrometeoroid Capture

2014

Mark C. Price
Anton T. Kearsley
Penelope J. Wozniakiewicz
John Spratt
Mark J. Burchell
M. J. Cole
P. Anz-Meador
J.-C. Liou
D. K. Ross
J. Opiela
G.W. Grime
R.P. Webb
C. Jeynes
Palitsin. V. V.
Julien L. Colaux
T. Griffin
L. Gerlach

Hypervelocity impact features have been recognized on painted surfaces returned from the Hubble Space Telescope (HST). Here we describe experiments that help us to understand their creation, and the preservation of micrometeoroid (MM) remnants. We simulated capture of silicate and sulfide minerals on the Zinc orthotitanate (ZOT) paint and Al alloy plate of the Wide Field and Planetary Camera 2 (WFPC2) radiator, which was returned from HST after 16 years in low Earth orbit (LEO). Our results also allow us to validate analytical methods for identification of MM (and orbital debris) impacts in LEO.

Keywords:

Scanning electron microscope
Hypervelocity
Astronomy
Wide Field and Planetary Camera 2
Optics
Spitzer Space Telescope
Micrometeoroid
Digital elevation model
Physics
Astrobiology
low earth orbit
hubble space telescope
Space debris

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