The surficial nature of lunar swirls as revealed by the Mini-RF instrument

• Published in: Icarus (New York, N.Y. 1962) Vol. 215; no. 1; pp. 186 - 196
• Main Authors: Neish, C.D., Blewett, D.T., Bussey, D.B.J., Lawrence, S.J., Mechtley, M., Thomson, B.J.
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier Inc 01.09.2011; Elsevier
• Subjects: Astronomy; Earth, ocean, space; Exact sciences and technology; Moon; Moon, Surface; Radar observations; Solar system; Moon; Moon, Surface; Radar observations; Circular polarization; Roughness; Reflectivity; Surface phenomena; Albedo; Radar observation; Radar imaging; Anomaly; Solar system; Magnetic fields; Solar wind; Age
• ISSN: 0019-1035; 1090-2643
• DOI: 10.1016/j.icarus.2011.06.037

► New imaging data of the lunar swirls from NASA’s Lunar Reconnaissance Orbiter. ► First global views of the lunar swirls at radar wavelengths (12.6 cm and 4.2 cm). ► The average radar properties of the lunar swirls are identical to non-swirl regions. ► This implies that swirls are related to a very thin (<few dm) surface phenomenon. ► Data from one crater support origin from solar wind interaction with magnetic field. Lunar swirls are optically bright, sinuous albedo features found on the Moon. The Mini-RF synthetic aperture radar on the Lunar Reconnaissance Orbiter has provided a comprehensive set of X- and S-Band radar images of these enigmatic features, including the first radar observations of swirls on the farside of the Moon. A few general remarks can be made about the nature of the lunar swirls from this data set. First, the average radar properties of lunar swirls are identical to nearby non-swirl regions, in both total radar backscatter and circular polarization ratio (CPR). This implies that average centimeter-scale roughness and composition within the high-albedo portions of the swirls do not differ appreciably from the surroundings, and that the high optical reflectance of the swirls is related to a very thin surface phenomenon (less than several decimeters thick) not observable with X- or S-Band radar. Secondly, bright swirl material appears to be stratigraphically younger than a newly discovered impact melt flow at Gerasimovich D. This observation indicates that the swirls are capable of forming over timescales less than the age of the crater. The Mini-RF data set also provides clues to the origin of the lunar swirls. In at least one case, the presence of an enhanced crustal magnetic field appears to be responsible for the preservation of a high-albedo ejecta blanket around an otherwise degraded crater, Descartes C. The degree of degradation of Descartes C suggests it should not be optically bright, yet it is. This implies that the enhanced albedo is related to its location within a magnetic anomaly, and hence supports an origin hypothesis that invokes interaction between the solar wind and the magnetic anomaly.