Press Release

The moon’s south pole: Very high resolution, radar images find rocks abundant, but no ice sheets

By SpaceRef Editor
October 18, 2006
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ITHACA, N.Y. — Using the highest resolution radar-signal images ever made of the moon – images from the National Science Foundation’s (NSF) Arecibo Telescope in Arecibo, P.R., and the NSF’s Robert C. Byrd Telescope in Green Bank, W.Va. – planetary astronomers have found no evidence for ice in craters at the lunar south pole. Cornell University, Smithsonian Institution and Australian scientists report the findings in the latest Nature (Oct. 19, 2006).

“These new results do not preclude ice being present as small grains in the lunar soil based on the Lunar Prospector’s discovery of enhanced hydrogen concentrations at the lunar poles,” said Donald Campbell, Cornell professor of astronomy and a principal investigator. “There is always the possibility that concentrated deposits exist in a few of the shadowed locations not visible to radars on Earth, but any current planning for landers or bases at the lunar poles should not count on this.”

Image courtesy of D. Campbell (Cornell), B. Campbell (Smithsonian) and L. Carter (Smithsonian) This radar image of the south pole region of the moon is about 250 km by 100 km. Shackleton crater (A) is 19 km in diameter. The Lunar Prospector orbiter impacted Shoemaker crater (B), 51 km in diameter. The south pole is about on the center of the left rim of Shackleton. The image was made in April 2005 by transmitting from Arecibo Observatory in Puerto Rico at 13 cm wavelength and receiving the radar echo with the Robert C. Byrd Green Bank Telescope in West Virginia. The underlying resolution of the image is about 20 m, the highest resolution radar image ever made of the moon.

Echoes from radar signals transmitted to the moon from the giant Arecibo telescope were received at the Green Bank telescope. These echoes allowed scientists from Cornell, the Smithsonian Institution and the Defence Science and Technology Organization in Australia to create images, offering the best view ever of the shadowed terrain at the lunar south pole.

Since the 1960s, theories have suggested that ice may exist deep inside impact craters in permanent shadow from the sun, where temperatures on the moon’s surface do not exceed minus 280 degrees Fahrenheit (or minus 173 Centigrade), at the poles. The theory was bolstered in 1992 when Earth-based radar telescopes located “ice deposits” inside impact craters at the poles of the planet Mercury.

The Lunar Prospector orbiter discovered concentrations of hydrogen at the moon’s poles. If this hydrogen were in the form of water molecules – still a subject of debate – then it would correspond to an average of 1 to 2 percent of water ice in the lunar soil in the shadowed terrain.

However, Earth-based radar measurements since the 1990s have consistently failed to detect ice deposits similar to those on Mercury. Since water ice would be a significant resource for any future lunar base, many of the instruments on NASA’s 2008 Lunar Reconnaissance Orbiter/Lunar Crater Observation and Sensing Satellite mission seek to learn if water ice is present in permanently shadowed craters.

Even in the lunar summer at the south pole, the sun barely edges above the horizon, thus the bottom impact craters never see the sun. Because of the tilt of the moon’s orbital plane relative to the Earth’s equatorial plane, the Earth can rise much higher above the horizon at the lunar south pole than the sun, so telescopes on the Earth can “see” some of the shadowed area. However, since that area is permanently in shadow, only radar can image that terrain.

Donald Campbell and Jean-Luc Margot of Cornell University, Bruce Campbell and Lynn Carter of the Smithsonian Institution, and Nicholas Stacy of the Australian Defence Science and Technology Organization conducted the research. Cornell’s National Astronomy and Ionosphere Center manages the Arecibo telescope, and the Green Bank Telescope is part of the National Radio Astronomy Observatory, which is operated by Associated Universities Inc. for the NSF.

SpaceRef staff editor.