1993
DOI: 10.1029/93je01581
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Mercury: full‐disk radar images and the detection and stability of ice at the North Pole

Abstract: The first full-disk radar images of Mercury were obtained on August 8 and 23, 1991. These images were constructed using the Very Large Array (VLA) in Socorro, New Mexico, to receive and map radar flux at 3.5 cm (X band) which was continuously transmitted from the 70-m Jet Propulsion Laboratory/Deep Space Network antenna at Goldstone, California. Approximately 77% of the surface was imaged, at resolutions as good as 150 km. About half of the hemisphere photographed by Mariner 10 was imaged, as well as most of t… Show more

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Cited by 198 publications
(195 citation statements)
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References 65 publications
(73 reference statements)
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“…Yet all three icy Galilean satellites show CBOE, with mean CPR values of 1.2 or greater [Ostro, 2002], increasing with increasing optical albedo. In addition, the polar deposits of Mercury exhibit a muted CBOE, thought to be caused by admixture of silicate particles into the ice regolith [Butler et al, 1993]. As the fraction of rock fragments increases, the CBOE decreases, but both Mercury and the icy Galilean satellites show that even significant amounts of silicates cannot totally remove the CBOE effect [Nozette et al, 1996].…”
Section: Discussionmentioning
confidence: 99%
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“…Yet all three icy Galilean satellites show CBOE, with mean CPR values of 1.2 or greater [Ostro, 2002], increasing with increasing optical albedo. In addition, the polar deposits of Mercury exhibit a muted CBOE, thought to be caused by admixture of silicate particles into the ice regolith [Butler et al, 1993]. As the fraction of rock fragments increases, the CBOE decreases, but both Mercury and the icy Galilean satellites show that even significant amounts of silicates cannot totally remove the CBOE effect [Nozette et al, 1996].…”
Section: Discussionmentioning
confidence: 99%
“…Radar backscatter from the lunar surface is modeled as a mixture of these specular and diffuse components. Diffuse scattering from rocky areas associated with fresh craters is assumed to have CPR of about 1.0; and ice is assumed to have CPR of 2.0, as observed in the polar features of Mercury and Mars and the surfaces of the icy Galilean satellites of Jupiter [Muhleman et al, 1991;Harmon and Slade, 1992;Butler et al, 1993;Ostro, 2002]. The differences in appearance between the lunar and mercurian polar craters suggest that more ice is present on Mercury than on the Moon, probably a result of the higher cometary flux near Mercury compared with the Moon [e.g., Hartmann et al, 1981] and the fact that the higher surface gravity on Mercury (~0.3 g) means that body will retain more water on its surface.…”
Section: Modeling the Radar Backscatter Of Rough And Icy Cratersmentioning
confidence: 99%
“…The volatiles producing the anomalously high same-sense radar backscatter could be pristine (outgassed from the interior) or brought in by cometary and meteoritic material [Butler et al, 1993] The importance of a definitive chemical identification of the anomolous radar-scattering deposits near the poles of Mercury has led us to explore their range of leakage neutron flux signatures. This study is motivated by previous simulations of neutron transport after production by galactic cosmic ray interactions in the Moon [Feldman et al, 1991] and in Mars [Feldman et al, 1993a].…”
Section: Introduction Earth-based Radar Observations Of Mercury In Thmentioning
confidence: 99%
“…These are based in part on the similarity of the backscatter signal to that from the icy Galilean satellites [Campbell et al, 1978] and from the polar caps of Mars [Muhleman et al, 1991]. Thermal modeling indicates that if regions within craters are permanently shielded from sunlight, the temperatures will be cold enough for water ice to be stably stored within them for billions of years [Paige et al, 1992;Butler et al, 1993]. Frozen CO2 was ruled out, however, on the basis of the very low temperature required for long-term stability.…”
Section: Introduction Earth-based Radar Observations Of Mercury In Thmentioning
confidence: 99%
“…Earth-based 12.6-cm radar observations show enhanced backscatter and circular polarization ratio only in association with the walls and proximal ejecta of impact craters or likely craters smaller than can be resolved by the imagery. No contiguous, high-backscatter regions covering crater floors, similar to polar features on Mercury attributed to ice (Butler et al, 1993;Harmon et al, 1994;Black et al, 2002), are evident (Stacy et al, 1997;Campbell et al, 2003). The Clementine spacecraft radio transmitter and an Earth-based receiver were used to acquire bistatic radar echoes from the Moon.…”
Section: Introductionmentioning
confidence: 99%