Finding a Crater to Call Home

NASA Views Landing Site Through Eyes of Future Moon Crew

This still is from a NASA simulation generated using high resolution topography, and shows the amount of solar illumination in the south polar region of the Moon over a solar day. Permanently shadowed regions can be easily identified in the simulation. Click here to view the quicktime feature from NASA.
Credit: NASA

NASA has obtained the highest resolution terrain mapping to date of the Moon’s rugged south polar region, with a resolution to 20 meters per pixel. Scientists at NASA’s Jet Propulsion Laboratory in Pasadena, Calif., collected the data using the facility’s Goldstone Solar System Radar located in California’s Mojave Desert. The imagery generated by the data has been incorporated into animation depicting the descent to the lunar surface of a future human lunar lander and a flyover of Shackleton Crater.

The mapping data collected indicate that the region of the Moon’s south pole near Shackleton Crater is much more rugged than previously understood. The Shackleton rim area is considered a candidate landing site for a future human mission to the Moon. NASA intends to return to the Moon by 2020. Experiments performed by future human explorers will help astrobiologists understand how organisms from Earth adapts to living beyond our planet. The Moon will also be a stepping-stone to further locations like Mars.

This graphic shows the resolution of the Moon’s south pole by the Clementine spacecraft’s optical system and then by the Goldstone Solar System Radar.
Credit: NASA
Previously, the highest resolution images of the south pole of the Moon were captured by the Clementine spacecraft. Images such as the one above revealed that the permanently shadowed lunar south pole shows evidence of meteor cratering and ice never exposed to direct sunlight.
Credit: NASA/DOD Clementine

"The south pole of the Moon certainly would be a beautiful place to explore," said Doug Cooke, deputy associate administrator for the Exploration Systems Mission Directorate at NASA Headquarters, Washington. "We now know the south pole has peaks as high as Mt. McKinley and crater floors four times deeper than the Grand Canyon. There are challenges that come with such rugged terrain, and these data will be an invaluable tool for advance planning of lunar missions."

Three times during a six-month period in 2006, scientists targeted the Moon’s south polar region using Goldstone’s 70-meter radar dish. The antenna, three-quarters the size of a football field, sent a 500-kilowatt strong, 90-minute long radar stream 231,800 miles to the Moon. The radar bounced off the rough-hewn lunar terrain over an area measuring about 400 miles by 250 miles. Signals were reflected back to two of Goldstone’s 34-meter antennas on Earth. The roundtrip time, from the antenna to the Moon and back, was about two-and-a-half seconds.

"I have not been to the Moon, but this imagery is the next best thing," said Scott Hensley, a scientist at JPL and lead investigator for the study. "With these data we can see terrain features as small as a house without even leaving the office."

Previously, the best resolution of the Moon’s south pole was generated by the Clementine spacecraft, which could resolve lunar terrain features near the south pole at 1 kilometer per pixel. The new resolution generated by JPL is 50 times more detailed.

The Clementine mission launched in 1994 and made scientific observations of the Moon and the near-Earth asteroid 1620 Geographos.
Credit: NASA

NASA’s Lunar Reconnaissance Orbiter will provide the next generation of lunar imaging and data. The spacecraft is scheduled to launch in late 2008. The Lunar Reconnaissance Orbiter Camera will retrieve high resolution images of the Moon’s surface and lunar poles with resolutions to 1 meter. These images will provide knowledge of polar illumination conditions, identify potential resources and hazards, and enable safe landing site selection. Other instruments aboard the orbiter will return data such as temperature maps, ultraviolet images, characterization of radiation on the Moon and a high resolution 3-D map. NASA’s quest for up-to-date imagery of the Moon also will benefit from international missions such as Japan’s Selene robotic probe.

Funding for the program was provided by NASA’s Exploration Systems Mission Directorate.


Related Web Sites

Astrobiology Roadmap Goal 6:Life’s Future on Earth and Beyond
Making a Home on the Moon
A Hitchhiker’s Guide to Astrobiology
Moonbase Divining for Lunar Water?
Bounce House on the Moon
Seeing the Moon Anew
Clementine Project (NASA)