Heather Cowardin, NASA JSC; Phillip Anz-Meador, Jacobs Technology; Jarod Melo, JACOBS; Mark Castaneda, NASA JSC Pathways Intern Program; Corbin Cruz, JACOBS; John Opiela, JACOBS; Christopher Cline, NASA Hypervelocity Impact Technology Team; Eric Christiansen, NASA Hypervelocity Impact Technology Team
Keywords: laboratory, fragmentation event,optical measurements, optical size estimation model
Abstract:
NASA’s Orbital Debris Program Office (ODPO) relies on measurements from optical, radar, and in situ measurements to facilitate the development of data-driven orbital debris environmental engineering models such as the NASA Orbital Debris Engineering Model (ORDEM). For optical measurements, the ODPO relies on ground-based optical telescopes to statistically assess objects in geosynchronous orbit (GEO) and, in the future, low Earth orbit (LEO). The data collected include the detected object’s orbital parameters, time of observation, and optical magnitude. The latter parameter can be converted to a size using NASA’s optical Size Estimation Model (oSEM). It is well known that the observed magnitude of orbital debris can vary based on an object’s material constituents, observational geometry, and the effects of space weathering.
To assess these magnitude variations, the ODPO uses the Optical Measurement Center at NASA Johnson Space Center to characterize a variety of materials and fragments from laboratory impact tests representative of fragments that constitute the orbital debris population. One experiment was DebriSat: a 56 kg spacecraft was built to incorporate structural elements of a modern LEO spacecraft and was subjected to a hypervelocity impact test at the U.S. Air Force’s Arnold Engineering Development Complex using test parameters that may be encountered in LEO. The DebriSat project has provided an abundance of information for assessing fragmentation debris in terms of material, color, shape, size, density, mass, and other derived parameters. Prior to the impact test, the ODPO collected spectral measurements on a subset of the materials used to construct DebriSat for a “ground-truth” of their optical properties. After the successful hypervelocity impact test, the DebriSat team observed a fine, dark dust coating all the fragments. Prior research has suggested that this came from ablated material deposited on the fragments during the impact test, causing a change in the reflective properties [1]. Given that this lower reflectivity on the DebriSat fragments will influence the laboratory-acquired magnitudes used to calculate size and inform potential updates to the oSEM, it is critical to assess if this darkening effect on the DebriSat fragments is a laboratory bias or something that could occur in on-orbit breakup events.
This paper will provide a brief overview of the OMC and DebriSat experiment, focused on the optical characterization of a subset of materials using broadband photometric measurements and spectroscopic measurements. In addition, elemental analysis of various DebriSat fragments and the soft-catch foam used in the hypervelocity experiment compared with pristine foam will be examined to further evaluate the source of the dark material coating all fragments. Finally, the authors will present a twofold plan 1) for assessing potential biases in laboratory impact experiments that could affect laboratory optical characterization and 2) mitigating biases when compared with ground-based optical telescopic measurements of the orbital debris environment.
Ref 1. Radhakrishnan, G., et al, “Debris Characterization, Albedo, and Plume Measurements from Laser Ablations of Satellite Materials in High-Vacuum and in Gaseous Ambients,” Proceedings of the 2018 AMOS Conference, Maui, Hawaii, September 2018.
Date of Conference: September 17-20, 2024
Track: Space Debris