Apollo 11 landed on the Moon on July 20th, 1969, a little after 4:00 in the afternoon Eastern Daylight Time. The Lunar Module, nicknamed Eagle and flown by Neil Armstrong and Edwin “Buzz” Aldrin, touched down near the southern rim of the Sea of Tranquility, one of the large, dark basins that contribute to the Man in the Moon visible from Earth. Armstrong and Aldrin spent about two hours outside the LM setting up experiments and collecting samples. At one point, Armstrong ventured east of the LM to examine a small crater, dubbed Little West, that he’d flown over just before landing.
The trails of disturbed regolith created by the astronauts’ boots are still clearly visible in photographs of the landing site taken by the Lunar Reconnaissance Orbiter (LRO) narrow-angle camera (LROC) more than four decades later.
LROC imagery makes it possible to visit the landing site in a whole new way by flying around a three-dimensional model of the site. LROC scientists created the digital elevation model using a stereo pair of images. Each image in the pair shows the site from a slightly different angle, allowing sophisticated software to infer the shape of the terrain, similar to the way that left and right eye views are combined in the brain to produce the perception of depth.
The animator draped an LROC photograph over the terrain model. He also added a 3D model of the LM descent stage—the real LM in the photograph looks oddly flat when viewed at an oblique angle.
Although the area around the site is relatively flat by lunar standards, West Crater (the big brother of the crater visited by Armstrong) appears in dramatic relief near the eastern edge of the terrain model. Ejecta from West comprises the boulders that Armstrong had to avoid as he searched for a safe landing site.
Apollo 11 was the first of six increasingly ambitious crewed lunar landings. The exploration of the lunar surface by the Apollo astronauts, when combined with the wealth of remote sensing data now being returned by LRO, continues to inform our understanding of our nearest neighbor in space.
While the moon’s surface is battered by millions of craters, it also has over 200 holes – steep-walled pits that in some cases might lead to caves that future astronauts could explore and use for shelter, according to new observations from NASA’s Lunar Reconnaissance Orbiter (LRO) spacecraft.
The pits range in size from about 5 meters (~5 yards) across to more than 900 meters (~984 yards) in diameter, and three of them were first identified using images from the Japanese Kaguya spacecraft. Hundreds more were found using a new computer algorithm that automatically scanned thousands of high-resolution images of the lunar surface from LRO’s Narrow Angle Camera (NAC).
“Pits would be useful in a support role for human activity on the lunar surface,” said Robert Wagner of Arizona State University, Tempe, Arizona. “A habitat placed in a pit — ideally several dozen meters back under an overhang — would provide a very safe location for astronauts: no radiation, no micrometeorites, possibly very little dust, and no wild day-night temperature swings.” Wagner developed the computer algorithm, and is lead author of a paper on this research now available online in the journal Icarus.
This is a spectacular high-Sun view of the Mare Tranquillitatis pit crater
revealing boulders on an otherwise smooth floor. This image from LRO’s NAC
is 400 meters (1,312 feet) wide, north is up.
Image Credit: NASA/GSFC/Arizona State University
Most pits were found either in large craters with impact melt ponds – areas of lava that formed from the heat of the impact and later solidified, or in the lunar maria – dark areas on the moon that are extensive solidified lava flows hundreds of miles across. In ancient times, the maria were thought to be oceans; “maria” is the Latin word for “seas.” Various cultures have interpreted the patterns formed by the maria features in different ways; for example, some saw the face of a man, while others saw a rabbit or a boy carrying a bundle of sticks on his back.
The pits could form when the roof of a void or cave collapses, perhaps from the vibrations generated by a nearby meteorite impact, according to Wagner. However, he noted that from their appearance in the LRO photos alone, there is little evidence to point to any particular cause. The voids could be created when molten rock flowed under the lunar surface; on Earth, lava tubes form when magma flows beneath a solidified crust and later drains away. The same process could happen on the moon, especially in a large impact crater, the interior of which can take hundreds of thousands of years to cool, according to Wagner. After an impact crater forms, the sides slump under lunar gravity, pushing up the crater’s floor and perhaps causing magma to flow under the surface, forming voids in places where it drains away.
Exploring impact melt pits would pin down the nature of the voids in which they form. “They are likely due to melt flow within the pond from uplift after the surface has solidified, but before the interior has cooled,” said Wagner. “Exploring impact melt pits would help determine the magnitude of this uplift, and the amount of melt flow after the pond is in place.”
Exploring the pits could also reveal how oceans of lava formed the lunar maria. “The mare pits in particular would be very useful for understanding how the lunar maria formed. We’ve taken images from orbit looking at the walls of these pits, which show that they cut through dozens of layers, confirming that the maria formed from lots of thin flows, rather than a few big ones. Ground-level exploration could determine the ages of these layers, and might even find solar wind particles that were trapped in the lunar surface billions of years ago,” said Wagner.
To date, the team has found over 200 pits spread across the melt ponds of 29 craters, which are considered geologically young “Copernican” craters at less than a billion years old; eight pits in the lunar maria, three of which were previously known from images from the Japanese Kaguya orbiter; and two pits in highlands terrain.
The general age sequence matches well with the pit distributions, according to Wagner. “Impact melt ponds of Copernican craters are some of the younger terrains on the moon, and while the maria are much older at around three billion years old, they are still younger and less battered than the highlands. It’s possible that there’s a ‘sweet spot’ age for pits, where enough impacts have occurred to create a lot of pits, but not enough to destroy them,” said Wagner.
There are almost certainly more pits out there, given that LRO has only imaged about 40 percent of the moon with appropriate lighting for the automated pit searching program, according to Wagner. He expects there may be at least two to three more mare pits and several dozen to over a hundred more impact melt pits, not including any pits that likely exist in already-imaged areas, but are too small to conclusively identify even with the NAC’s resolution.
These images from NASA’s LRO spacecraft show all of the known mare pits and highland pits. Each image is 222 meters (about 728 feet) wide. Image Credit: NASA/GSFC/Arizona State University
“We’ll continue scanning NAC images for pits as they come down from the spacecraft, but for about 25 percent of the moon’s surface area (near the poles) the sun never rises high enough for our algorithm to work,” said Wagner. “These areas will require an improved search algorithm, and even that may not work at very high latitudes, where even a human has trouble telling a pit from an impact crater.”
The next step would be to tie together more datasets such as composition maps, thermal measurements, gravity measurements, etc., to gain a better understanding of the environments in which these pits form, both at and below the surface, according to Wagner.
“The ideal follow-up, of course, would be to drop probes into one or two of these pits, and get a really good look at what’s down there,” adds Wagner. “Pits, by their nature, cannot be explored very well from orbit — the lower walls and any floor-level caves simply cannot be seen from a good angle. Even a few pictures from ground-level would answer a lot of the outstanding questions about the nature of the voids that the pits collapsed into. We’re currently in the very early design phases of a mission concept to do exactly this, exploring one of the largest mare pits.”
The research was funded by NASA’s LRO project. Launched on June 18, 2009, LRO has collected a treasure trove of data with its seven powerful instruments, making an invaluable contribution to our knowledge about the moon. LRO is managed by NASA’s Goddard Space Flight Center in Greenbelt, Maryland, for the Science Mission Directorate at NASA Headquarters in Washington.
Sunday July 20th will be the 45th anniversary of the Apollo 11 Moon landing. Here is a video released by NASA today showing the complete lunar EVA with restored imagery:
Caption:
Original Mission Video as aired in July 1969 depicting the Apollo 11 astronauts conducting several tasks during extravehicular activity (EVA) operations on the surface of the moon. The EVA lasted approximately 2.5 hours with all scientific activities being completed satisfactorily.
The Apollo 11 (EVA) began at 10:39:33 p.m. EDT on July 20, 1969 when Astronaut Neil Armstrong emerged from the spacecraft first. While descending, he released the Modularized Equipment Stowage Assembly on the Lunar Module’s descent stage. A camera on this module provided live television coverage of man’s first step on the Moon.
On this, their one and only EVA, the astronauts had a great deal to do in a short time. During this first visit to the Moon, the astronauts remained within about 100 meters of the lunar module, collected about 47 pounds of samples, and deployed four experiments. After spending approximately 2 hours and 31 minutes on the surface, the astronauts ended the EVA at 1:11:13 a.m. EDT on July 21.
In cooperation with the National Space Society of North Texas, the Museum once again celebrates space exploration with MOON DAY, July 19, 2014. Come and experience a full day of family-oriented activities, demonstrations, and programs, marking the 45th anniversary of the first manned Moon landing (the actual landing was on July 20).
THE FIRST 250 CHILDREN to arrive will receive a free “Lunar Sample Bag” courtesy of Moonlite Printing & Graphics of Carrollton, full of magazines, stickers, activity books, posters and other materials of interest to space flight enthusiasts of all ages.
OVER 25 EXHIBITORS will offer fascinating displays and activities such as a close-up look at a meteorite, robotics demonstrations, space art, re-creating Moon craters, and a SAFE look directly at the sun through specially-equipped telescopes.
THREE PORTABLE PLANETARIUMS will be featured this year, all with different programs, to give visitors a glimpse of the night sky throughout the day!
FASCINATING PROGRAMS for all ages will include a look at life on Mars, “Cosmic Chemistry,” and the story of how Dr. James Carter of the University of Texas at Dallas developed simulated moon soil—presented by Dr. Carter himself!
BUILD AND LAUNCH A MODEL ROCKET!—Our younger visitors can attend a model rocket-building class courtesy of the Dallas Area Rocket Society from 1:30-3:15 p.m. A $25.00 fee includes all materials including a beginner’s level model rocket and engine, a one-year membership to the Dallas Area Rocket Society, and an opportunity to launch the model rocket at a supervised Dallas Area Rocket Society launch event. Students can enroll in advance or sign up at the door. Call (214) 350-4215 for details.
GIRL SCOUTS, BOY SCOUTS, AND CUB SCOUTS can meet various badge and pin requirements through participation in specific Moon Day activities. No registration is required, and the qualifying activities are presented throughout the entire day.
CONTINUING PROFESSIONAL EDUCATION (CPE) CREDITS can be earned by DISD teachers attending any one of several presentations throughout the day—get a head start on your 2014-2015 requirements!
P.S. If you are not living near Dallas, you might check to see if a museum in your area is hosting a Moon Day event of their own.
1. Monday, June 30, 2014: 2-3:30 PM PDT (5-6:30 PM EDT, 4-5:30 PM CDT): DR. DOUG PLATA returns with more on his Lunar Cots & cislunar work, including ISDC presentations and upcoming AIAA Space 2014 presentations.
2. SPECIAL TIME: Tuesday, July 1, 2014:, 2-3 PM PDT (5-6 PM EDT, 4-5 PM CDT): We welcome back MIKE GOLD, the Chair of the Commercial Space Transportation Advisory Committee (“COMSTAC”) . Mr. Gold is also the Bigelow Aerospace‘s director of D.C. Operations and Business Growth. Mr. Gold’s focus for this program is COMSTAC.
3. Friday, July 4, 2014, 9:30 -11 AM PDT (12;30-2 PM EDT; 11:30-1 PM CDT): No show today due to the start of the July 4th holiday weekend. .
4. Sunday, July 6, 2014, 12-1:30 PM PDT (3-4:30 PM EDT, 2-3:30 PM CDT). No show today due to the July 4th holiday weekend.
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