Lunar Reconnaissance Orbiter LROC images - August 3-5, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• Remnants of the Imbrium impact (Released 3 August 2010)
  Mare basalts embayed ejecta structures formed by the massive Imbrium impact.
• Concentric crater (Released 4 August 2010)
  The inner rim of Gruithuisen K.
• A path not taken (Released 5 August 2010)
  Mare surface in Sinus Aestuum near a lunar exploration site proposed in the late 1950s.

Lunar Reconnaissance Orbiter LROC and LOLA images - April 20-30, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• Dante Crater Constellation Region of Interest (Released 20 April 2010)
  Highlands terrain inside the Dante Crater Constellation Site.
• Craters on the Schrodinger pyroclastic cone (Released 22 April 2010)
  LROC NAC closeup clustered craters on the Schrodinger pyroclastic cone, one of the NASA Constellation regions of interest.
• Constellation Region of Interest at Mare Tranquillitatis (Released 27 April 2010)
  Close up of a northwest trending wrinkle ridge in the high-Ti basaltic lava plains of Mare Tranquillitatis, near a Constellation region of interest.
• Floor of Tsiolkovskiy - Constellation Region of Interest (Released 30 April 2010)
  LROC NAC view of boulders on an outlying rampart of the complex central peak of Tsiolkovskiy crater within the Constellation region of interest.

Lunar Orbiter Laser Altimeter (LOLA) Image of the Week:

• Copernicus (Released 30 April 2010)
  800 million years ago an impactor struck the eastern extent of Oceanus Procellarum, the "Ocean of Storms."

Lunar Reconnaissance Orbiter LROC images - April 13-16, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• The Apollo 15 Lunar Laser Ranging Retroreflector - A Fundamental Point on the Moon! (Released 13 April 2010)
  The Apollo 15 Lunar Laser Ranging RetroReflector (LRRR) array is one of four such working arrays on the surface of the Moon.
• Exposed Fractured Bedrock in the Central Peak of the Anaxagoras Crater (Released 14 April 2010)
  NAC image of the Anaxagoras crater floor, including a portion of the crater's anorthositic central uplift.
• Rimae Prinz Region - Constellation Region of Interest (Released 15 April 2010)
  A sinuous rille created by a lava flow snakes around the base of a massif in the Prinz-Harbinger region on the Moon.
• Retracing the Steps of Apollo 15: Constellation Region of Interest (Released 16 April 2010)
  The third and final EVA of Apollo 15 brought the astronauts to the edge of Hadley Rille (lower left).

Lunar Reconnaissance Orbiter LROC images - April 2-8, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• Alphonsus crater mantled floor fracture (Released 2 April 2010)
  LROC NAC closeup of a fracture in the floor of Alphonsus crater.
• Each crater tells a story (Released 7 April 2010)
  The unusual shapes of craters at the Flamsteed Constellation region of interest provide information about the thickness of the lunar regolith in this region.
• Graben and Pyroclastics in SW Mare Humorum (Released 8 April 2010)
  A small graben (28 m in width) in a pyroclastic mantling deposit in the SW portion of Mare Humorum.

Lunar Reconnaissance Orbiter LROC images - March 26-April 1, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• Two-toned Impact Crater in Balmer Basin: A Reflection of the Target?(Released 26 March 2010)
  Materials excavated during formation of this ~450 m diameter impact crater have an unusual two-toned character, likely a reflection of heterogeneity in the target materials.
• Chain of secondary craters in Mare Orientale (Released 29 March 2010)
  A small secondary crater chain near the southwestern margin of Mare Orientale, within the Inner Rook Mountains.
• Apollo Basin: Mare in a Sea of Highlands (Released 30 March 2010)
  High resolution LROC image of floor of the Apollo Basin, a large (538 km diameter) double-ringed impact crater in the southern hemisphere of the far side.
• Hortensius Domes - Constellation Region of Interest (Released 1 April 2010)
  Summit crater of Hortensius Dome Phi.

Lunar Reconnaissance Orbiter LROC images - March 15-19, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• Soviet Union Lunar Sample Return Missions (Released 15 March 2010)
  On February 21, 1972, Luna 20 soft landed in the rugged highlands between Mare Fecunditatis and Mare Crisium.
• Soviet Union Lunar Rovers (Released 17 March 2010)
  Soviet robotic lander Luna 17 still sitting on Mare Imbrium where it delivered the Lunokhod 1 Rover in November 1970.
• Luna 21 Lander (Released 19 March 2010)
  Luna 21 lander delivered the Lunokhod 2 rover to the floor of Le Monnier crater in January 1973.

Lunar Reconnaissance Orbiter LROC images - March 15-19, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• Soviet Union Lunar Sample Return Missions (Released 15 March 2010)
  On February 21, 1972, Luna 20 soft landed in the rugged highlands between Mare Fecunditatis and Mare Crisium.
• Soviet Union Lunar Rovers (Released 17 March 2010)
  Soviet robotic lander Luna 17 still sitting on Mare Imbrium where it delivered the Lunokhod 1 Rover in November 1970.
• Luna 21 Lander (Released 19 March 2010)
  Luna 21 lander delivered the Lunokhod 2 rover to the floor of Le Monnier crater in January 1973.

Researcher solves 37-year old space mystery

A researcher from The University of Western Ontario has helped solve a 37-year old space mystery using lunar images released yesterday by NASA and maps from his own atlas of the moon.

Phil Stooke, a professor cross appointed to Western's Departments of Physics & Astronomy and Geography, published a major reference book on lunar exploration in 2007 entitled, "The International Atlas of Lunar Exploration."

Yesterday, images and data from Nasa's Lunar Reconnaissance Orbiter (LRO) were posted. The LRO, scheduled for a one year exploration mission about 31 miles above the lunar surface, will produce a comprehensive map, search for resources and potential safe landing sites and measure lunar temperatures and radiation levels.

Using his atlas and the NASA images, Stooke pinpointed the exact location of the Russian rover Lunokhod 2, discovering tracks left by the lunar sampler 37 years ago after it made a 35-kilometre trek. The journey was the longest any robotic rover has ever been driven on another celestial body.

As soon as the NASA photos were released, scientists around the world, including Stooke, began work to locate the rover. Stooke set up a searchable image database and located the photograph he needed, among thousands of others.

"The tracks were visible at once," says Stooke. "Knowing the history of the mission, it's possible to trace the rover's activities in fine detail. We can see where it measured the magnetic field, driving back and forth over the same route to improve the data. And we can also see where it drove into a small crater, and accidentally covered its heat radiator with soil as it struggled to get out again. That ultimately caused it to overheat and stop working. And the rover itself shows up as a dark spot right where it stopped."

The find, he adds will mean that older maps published by Russia will now need to be revised.

Stooke says that NASA scientists have used his atlas in both preparation and data recovery.

His next project is a similar volume on Mars exploration which will include the best maps of the moons of Mars.

Provided by University of Western Ontario

Planetary Data System Releases New Lunar Datasets

Officials at the American space agency announce that the archiving program Planetary Data System (PDS) released yesterday a new series of datasets on the our Moon. The information that were included in the releases were all collected by the seven advanced scientific instruments aboard the NASA Lunar Reconnaissance Orbiter (LRO), currently in orbit around Earth's natural satellite. Being a public-funded project, the PDS is available to everyone and can be viewed here.

“The Planetary Data System is a NASA-funded program to archive data from past and present planetary missions as well as astronomical observations and laboratory data. The purpose of the Planetary Data System is to make available to the public the fruits of NASA funded research and to allow advanced research on solar system science,” says the deputy project scientist for the LRO mission, Dr John Keller. The expert holds an appointment at the Greenbelt, Maryland-based NASA Goddard Space Flight Center. He adds that the new online resource will provide interested members of the general public with new maps and calibrated images of the Moon, all collected by the LRO.

Adds Keller of the spacecraft: “We're able to take advantage of the close proximity of the Moon, compared to other objects in the solar system, to transmit data from LRO back to Earth at a very high rate. The first data release is 55 terabytes. The one year exploration mission will deliver 130 terabytes of data, enabling a more detailed study our nearest celestial neighbor. We expect LRO to provide more data than all of the previous planetary missions combined.” The probe was launched last year alongside the Lunar Crater Observation and Sensing Satellite (LCROSS), which managed to demonstrate once and for all that water-ice exists in ever-shadowed craters at the lunar south pole.

The PDS will mostly include low-level form images that will not be highly processed. One reason for why NASA decided to take this approach is the fact that this provides researchers with more flexibility in dealing with the datasets. Some highly-processed and calibrated images will also be made available to both scientists and the general public. This is not the first information that the LRO collected to be published. Earlier this year, the LROC team published hundreds of Narrow Angle Cameras images, so as to give scientists a head-start before the massive volume of lunar-related information was brought online.

New Lunar Images and Data Available to the Public

The public can follow along with NASA on its journey of lunar discovery. On March 15, the publicly accessible Planetary Data System will release data sets from the seven instruments on board NASA's Lunar Reconnaissance Orbiter.

"The Planetary Data System is a NASA funded program to archive data from past and present planetary missions as well as astronomical observations and laboratory data," said Dr. John Keller, LRO Deputy Project Scientist from NASA Goddard Space Flight Center in Greenbelt, Md. "The purpose of the Planetary Data System is to make available to the public the fruits of NASA funded research and to allow advanced research on solar system science."

Each of the seven instruments is unique and will provide data in different formats to the Planetary Data System. Much of the data will be in a relatively low level form, not highly processed, which allows researchers to maximize flexibility in working with the data. The instrument teams will also provide higher level data products in the form of maps and calibrated images for the general public. Many of the images can be accessed using a computer with an internet browser.

Prior to the formal release of LRO data, the Lunar Reconnaissance Orbiter Camera team released several hundred images from the pair of Narrow Angle Cameras on-board the spacecraft. These images were released to give researchers a head start on using the data before the tidal wave of data was unleashed.

"We're able to take advantage of the close proximity of the Moon, compared to other objects in the solar system, to transmit data from LRO back to Earth at a very high rate," said Keller. "The first data release is 55 terabytes. The one year exploration mission will deliver 130 terabytes of data, enabling a more detailed study our nearest celestial neighbor. We expect LRO to provide more data than all of the previous planetary missions combined."

LRO was mandated to release data to the Planetary Data System beginning six months after initial operation. Some of the higher level data products require the full year of measurements and won't be released until after the end of the exploration mission. LRO will move into its science phase in September, when the program management responsibility moves from the Exploration Systems Mission Directorate to the Science Mission Directorate at NASA Headquarters.

LRO is scheduled for a one year exploration mission in a polar orbit about 31 miles above the lunar surface. During this time, LRO will produce a comprehensive map of the lunar surface in unprecedented detail, search for resources and potential safe landing sites for a potential future return to the moon and measure lunar temperatures and radiation levels.

The lunar bound spacecraft launched from Kennedy Space Center, Fla. on June 18, 2009. Since that time the spacecraft has completed calibration and commissioning. LRO formally began its detailed survey of the moon in September 2009. First results from the mission included - new looks at the Apollo landing sites; indications that permanently shadowed and nearby regions may harbor water and hydrogen; observations that large areas in the permanently shadowed regions are colder than Pluto; and detailed information on lunar terrain. LRO also supported the Lunar Crater Observation and Sensing Satellite impact, first by helping to select a promising site and second by observing both the expanding plume that arose after the impact and the evolving temperature at the impact site.

NASA's Goddard Space Flight Center built and manages the mission for the Exploration Systems Mission Directorate at NASA Headquarters in Washington. The Institute for Space Research, Moscow, provides the neutron detector aboard the spacecraft.

To access the Planetary Data System, go to: http://pds.jpl.nasa.gov/

More information can be found about LRO at: http://www.nasa.gov/lro

HiRISE images for March 10, 2010

The following new captioned and spotlight images taken by the High Resolution Imaging Science Experiment (HiRISE) on the Mars Reconnaissance Orbiter spacecraft are now available:

• At the Summit of Arsia Mons Volcano
  Like the other major shield volcanoes on Mars, Arsia Mons has a caldera (large volcanic crater) at its summit.
• Northern Hemisphere Gullies with Layers
  This observation shows northern hemisphere gullies on a layered crater wall.
• Candidate Landing Site in Possible Salt Playa
  This image covers part of a candidate landing site that appears to be a shallow depression with a deposit perhaps consisting of chlorides, like table salt.
• Cerberus Fossae East of the Head of Athabasca Valles
  This image shows part of Cerberus Fossae, a long system of extensional (normal) faults arranged in trough-bounding (graben-bounding) pairs. Cerberus Fossae served as the source of a large volcanic eruption that draped Athabasca Valles in lava.
• A Burst of Spring
  In the winter a layer of carbon dioxide ice (dry ice) covers the north polar sand dunes. In the spring the sublimation of the ice (going directly from ice to gas) causes a host of uniquely Martian phenomena.

Lunar Reconnaissance Orbiter LROC images - February 1-5, 2010

The following featured images taken by the Lunar Reconnaissance Orbiter Camera (LROC) are now available:

• Plato Crater Constellation Region of Interest (Released 2 February 2010)
  The Constellation Program region of interest northwest of Plato crater exhibits a wide variety of geologic features.
• Out of the Shadows: Impact Melt Flow at Byrgius A Crater (Released 2 February 2010)
  Spectacularly preserved viscous flow on the NE rim of Byrgius A (19 km diameter) crater.
• Riccioli Crater: Cracked, Melted, and Draped (Released 4 February 2010)
  High-resolution LROC view of part of the floor of Riccioli Crater, near the center of the Constellation region of interest.

First Moon Images From NASA's Lunar Reconnaissance Orbiter

NASA's Lunar Reconnaissance Orbiter has transmitted its first images since reaching the moon on June 23. The spacecraft's two cameras, collectively known as the Lunar Reconnaissance Orbiter Camera, or LROC, were activated June 30. The cameras are working well and have returned images of a region in the lunar highlands south of Mare Nubium (Sea of Clouds).

As the moon rotates beneath LRO, LROC gradually will build up photographic maps of the lunar surface.

"Our first images were taken along the moon's terminator -- the dividing line between day and night -- making us initially unsure of how they would turn out," said LROC Principal Investigator Mark Robinson of Arizona State University in Tempe. "Because of the deep shadowing, subtle topography is exaggerated, suggesting a craggy and inhospitable surface. In reality, the area is similar to the region where the Apollo 16 astronauts safely explored in 1972. While these are magnificent in their own right, the main message is that LROC is nearly ready to begin its mission."

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Larger version of bottom image

These images show cratered regions near the moon's Mare Nubium region, as photographed by the Lunar Reconnaissance Orbiter's LROC instrument. Each image shows a region 1,400 meters (0.87 miles) wide. the bottoms of both images face lunar north. The image below shows the location of these two images in relation to each other. Credit: NASA/Goddard Space Flight Center/Arizona State University

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First Moon Photo from Just-Arrived NASA Probe

NASA's LCROSS probe beamed this view of the moon's Mendeleev region, an ancient impact basin with relatively uniform floor deposits on the far side, during afirst flyby on June, 23, 2009. The probe's position at the time of the image is also shown. The probe will ultimately crash into the lunar surface to hunt for water ice on Oct. 9, 2009. Credit: NASA

A new NASA probe beamed down live images of the moon early Tuesday to reveal a stark surface littered with craters, as it flew toward a planned crash at the lunar south pole later this year.

The $79 million Lunar Crater Observation and Sensing Satellite, or LCROSS, launched toward the moon on June 18 and began sending images today at 8:20 a.m. EDT (1220 GMT).

LCROSS and an attached empty Centaur rocket stage swooped down near the lunar south pole and continued north along the far side of the moon. The spacecraft is getting into position to crash down on the surface on Oct. 9.

Read full story at SPACE.com

NASA Lunar Reconnaissance Orbiter Successfully Enters Moon Orbit

After a four and a half day journey from the Earth, the Lunar Reconnaissance Orbiter, or LRO, has successfully entered orbit around the moon. Engineers at NASA's Goddard Space Flight Center in Greenbelt, Md., confirmed the spacecraft's lunar orbit insertion at 6:27 a.m. EDT Tuesday.

During transit to the moon, engineers performed a mid-course correction to get the spacecraft in the proper position to reach its lunar destination. Since the moon is always moving, the spacecraft shot for a target point ahead of the moon. When close to the moon, LRO used its rocket motor to slow down until the gravity of the moon caught the spacecraft in lunar orbit.

"Lunar orbit insertion is a crucial milestone for the mission," said Cathy Peddie, LRO deputy project manager at Goddard. "The LRO mission cannot begin until the moon captures us. Once we enter the moon's orbit, we can begin to buildup the dataset needed to understand in greater detail the lunar topography, features and resources. We are so proud to be a part of this exciting mission and NASA's planned return to the moon."

A series of four engine burns over the next four days will put the satellite into its commissioning phase orbit. During the commissioning phase each of its seven instruments is checked out and brought online. The commissioning phase will end approximately 60 days after launch, when LRO will use its engines to transition to its primary mission orbit.

For its primary mission, LRO will orbit above the moon at about 31 miles, or 50 kilometers, for one year. The spacecraft's instruments will help scientists compile high resolution, three-dimensional maps of the lunar surface and also survey it at many spectral wavelengths.

The satellite will explore the moon's deepest craters, examining permanently sunlit and shadowed regions, and provide understanding of the effects of lunar radiation on humans. LRO will return more data about the moon than any previous mission.

For more information about the LRO mission, visit: http://www.nasa.gov/lro

New NASA Missions to Reach Moon Tuesday, Sending Back Live Video

Overview
After its successful launch, LCROSS is now on its way to the moon. Approximately five days after launch, the spacecraft will perform a lunar swingby to enter into an elongated polar Earth orbit to position LCROSS for impact on the lunar south pole (see mission overview video). Shortly after periselene, the time of closest approach to the lunar surface, the LCROSS science payload will be switched on for the duration of one hour for calibration of its cameras and spectrometers.

Graphic visualizations of the early part of the LCROSS orbit leading up to lunar swingby at Launch +5 days. The blue line represents the Earth's orbit around the sun. The white circle is the moon's orbit around the Earth. The yellow line is the orbit of the LCROSS spacecraft. The intersection of the yellow line with the moon's orbit represents the Launch +5 days lunar swingby. Credit: NASA

Streaming Video Coverage of the Lunar Swingby
The LCROSS instrumentation will send back data to Earth for approximately one hour. The first 30 minutes will contain a view of the lunar surface from an altitude of approximately 9,000 km. The video feed is set to display one frame per second. During the latter 30 minutes, the spacecraft will perform multiple scans of the moon's horizon to calibrate its sensors. During this latter half hour, the video image will update only occasionally. The 3D visualization stream will show the spacecraft position and attitude throughout the swingby.

WASHINGTON -- Two NASA spacecraft will reach major mission milestones early Tuesday morning as they approach the moon -- one will send back live streaming imagery via the Internet as it swings by the moon, the other will insert itself into lunar orbit to begin mapping the moon's surface.

After a four and a half day journey to the moon, NASA's Lunar Reconnaissance Orbiter, or LRO, will be captured by the moon's gravity and prepare for the commissioning phase of its mission on June 23. NASA TV live coverage of LRO's orbit insertion begins at 5:30 a.m. EDT Tuesday, with the actual engine burn to begin orbit insertion starting at 5:47 a.m.

In addition to animation and footage of LRO, live interviews will be broadcast from NASA's Goddard Space Flight Center in Greenbelt, Md., with Cathy Peddie, LRO deputy project manager at Goddard; Jim Garvin, Goddard chief scientist; Laurie Leshin, Goddard deputy director for Science and Technology; Mike Wargo, NASA's chief lunar scientist in the Exploration Systems Mission Directorate at NASA Headquarters in Washington; Rich Vondrak, LRO project scientist at Goddard; and Craig Tooley, LRO project manager at Goddard.

At 8:20 a.m. Tuesday, the Science Operations Center at NASA's Ames Research Center in Moffett Field, Calif., will stream live telemetry-based spacecraft animation and the visible camera images from the Lunar Crater Observation and Sensing Satellite, or LCROSS, spacecraft as it swings by the moon before entering into a looping polar Earth orbit. Live video streaming via the Internet will last approximately one hour.

The live video streams of the LCROSS swingby will be available at:

http://www.nasa.gov/mission_pages/LCROSS/lunarswingby

The LCROSS swingby starts near the lunar south pole and continues north along the far side of the moon. The maneuver will put the LCROSS spacecraft and its spent second stage Centaur rocket in the correct flight path for the October impact near the lunar south pole. The swingby also will give the mission operations team the opportunity to practice the small trajectory correction maneuvers needed to target the permanently shadowed crater that will be selected by the LCROSS science team.

During the swingby, the science team will make measurements of the moon's surface and the lunar horizon to calibrate the spacecraft's cameras and spectrometers. The LCROSS visible spectrometer will make the first near-ultraviolet survey of the selected locations on the far-side of the moon giving scientists a unique look at the concentration of minerals and elements in the lunar soil.

LCROSS and its attached Centaur upper stage rocket separately will collide with the moon the morning of Oct. 9, 2009, creating a pair of debris plumes that will be analyzed for the presence of water ice or water vapor, hydrocarbons and hydrated materials.

The LRO and LCROSS missions are providing mission updates on Twitter at:

http://www.twitter.com/lro_nasa and http://www.twitter.com/lcross_nasa

For more information about NASA's LCROSS and LRO missions, visit:

http://www.nasa.gov/lro and http://www.nasa.gov/lcross

For NASA TV downlink information, schedules and links to streaming video, visit:

http://www.nasa.gov/ntv

NASA Returning to the Moon with First Lunar Launch in a Decade

NASA's LRO and LCROSS spacecraft on top of the Atlas V rocket launch from Complex 41 on Cape Canaveral Air Force Station. Photo credit: United Launch Alliance/Pat Corkery

NASA's Lunar Reconnaissance Orbiter launched at 5:32 p.m. EDT Thursday aboard an Atlas V rocket from Cape Canaveral Air Force Station in Florida. The satellite will relay more information about the lunar environment than any other previous mission to the moon.

The orbiter, known as LRO, separated from the Atlas V rocket carrying it and a companion mission, the Lunar Crater Observation and Sensing Satellite, or LCROSS, and immediately began powering up the components necessary to control the spacecraft. The flight operations team established communication with LRO and commanded the successful deployment of the solar array at 7:40 p.m. The operations team continues to check out the spacecraft subsystems and prepare for the first mid-course correction maneuver. NASA scientists expect to establish communications with LCROSS about four hours after launch, at approximately 9:30 p.m.

"This is a very important day for NASA," said Doug Cooke, associate administrator for NASA's Exploration Systems Mission Directorate in Washington, which designed and developed both the LRO and LCROSS missions. "We look forward to an extraordinary period of discovery at the moon and the information LRO will give us for future exploration missions."

The spacecraft will be placed in low polar orbit about 31 miles, or 50 kilometers, above the moon for a one year primary mission. LRO's instruments will help scientists compile high resolution three-dimensional maps of the lunar surface and also survey it at many spectral wavelengths. The satellite will explore the moon's deepest craters, exploring permanently sunlit and shadowed regions, and provide understanding of the effects of lunar radiation on humans.

"Our job is to perform reconnaissance of the moon's surface using a suite of seven powerful instruments," said Craig Tooley, LRO project manager at NASA's Goddard Space Flight Center in Greenbelt, Md. "NASA will use the data LRO collects to design the vehicles and systems for returning humans to the moon and selecting the landing sites that will be their destinations."

High resolution imagery from LRO's camera will help identify landing sites for future explorers and characterize the moon's topography and composition. The hydrogen concentrations at the moon's poles will be mapped in detail, pinpointing the locations of possible water ice. A miniaturized radar system will image the poles and test communication capabilities.

"During the 60 day commissioning period, we will turn on spacecraft components and science instruments," explained Cathy Peddie, LRO deputy project manager at Goddard. "All instruments will be turned on within two weeks of launch, and we should start seeing the moon in new and greater detail within the next month."

"We learned much about the moon from the Apollo program, but now it is time to return to the moon for intensive study, and we will do just that with LRO," said Richard Vondrak, LRO project scientist at Goddard.

All LRO initial data sets will be deposited in the Planetary Data System, a publicly accessible repository of planetary science information, within six months of launch.

Goddard built and manages LRO. LRO is a NASA mission with international participation from the Institute for Space Research in Moscow. Russia provides the neutron detector aboard the spacecraft.

The LRO mission is providing updates via @LRO_NASA on Twitter. To follow, visit:

http://www.twitter.com/lro_nasa

For more information about the LRO mission, visit:

http://www.nasa.gov/lro

NASA | LRO/LCROSS Launch Prep Behind the Scenes with Jim Garvin

Jim Garvin, NASA Goddards Chief Scientist, gives his take on the LRO/LCROSS launch, NASAs first venture back to the moon in a decade. Be prepared for excitement and adventure!

NASA Return to Lunar Orbit Will Scout for Future Human Exploration

The Lunar Reconnaissance Orbiter, launching this week, will set the stage for the planned U.S. return to the moon by surveying locations and resources

Atop an Atlas 5 rocket at Cape Canaveral Air Force Station in Florida sits the first step in what will surely be a long and arduous task for NASA—returning humans to the moon. The Lunar Reconnaissance Orbiter, or LRO, set to lift off this week, will orbit the moon in search of potential landing sites and useful resources, such as water ice, that would facilitate a long-term human presence.

For starters, LRO will improve maps of the moon, says astrophysicist John Keller of the NASA Goddard Space Flight Center in Greenbelt, Md., deputy project scientist for the $500-million mission. "A point I like to make about LRO," he says, "is that when it comes to the shape of the moon, we actually know the shape of Mars much better than we do of the moon." Three-dimensional laser-altimetry data taken by LRO will help to close that gap.

Planetary scientist David Kring, a senior staff scientist at the Lunar and Planetary Institute in Houston, sounds a similar tone, noting that the orbiter "will be exploring regions of the moon that have been fuzzy or completely invisible to us in the past."

The satellite's polar orbit will allow it to focus on especially desirable regions for human activities. At the moon's poles, Keller explains, the fairly consistent low angle of the sun makes available essentially constant access to solar power and, potentially, stores of water frozen in permanently shadowed craters. (A companion spacecraft to LRO will seek out direct evidence of that water ice in October.)

Among the orbiter's seven scientific instruments is one with a distinctly human-focused assignment: The Cosmic Ray Telescope for the Effects of Radiation (CRaTER). It will seek to characterize and assess the physiological effects of high-energy cosmic rays. Earth's inhabitants are largely protected from cosmic radiation by the planet's atmosphere and magnetic field, but long-term residents of the moon would be exposed to potential cellular and genetic damage without proper shielding.

CRaTER has cosmic-ray detectors separated by a material known as tissue-equivalent plastic. That plastic mimics how biological tissue absorbs radiation, and the LRO mission is the first time it will find use outside Earth's protective influence, Keller says. "By looking at the difference" between the radiation registered by the detectors, he explains, "you can say something about how much [energy] was deposited into that plastic."

The LRO mission springs from NASA's Vision for Space Exploration, the Bush-era plan to return humans to the moon by 2020 on board Ares rockets currently in development to replace the space shuttle, which retires next year. But while the lunar timeline and the Ares program are under scrutiny by a blue-ribbon panel of independent experts convened by the White House, the robotic precursor to human exploration continues apace.

Kring says that even given the uncertainties in the future of manned spaceflight in the U.S., the lunar orbiter is a mission whose time has come. "Not only is this the right time to launch LRO, the LRO spacecraft should be the first in a small fleet of missions that expand our horizons and, simultaneously, provide opportunities to enhance our nation's technological capabilities," he says.

LRO/LCROSS Launch Moves Forward

The launch and mission teams for the Lunar Reconnaissance Orbiter and Lunar Crater Observation and Sensing Spacecraft missions met on Wednesday in Florida for the Flight Readiness Review, or FRR.

The teams announced that there are no major issues or concerns to hamper launch at this time.

Final spacecraft closeouts are underway at the launch pad and countdown dress rehearsal activities are planned for all day Thursday.

A Launch Readiness Review, or LRR, is scheduled for Monday at 9 a.m. EDT. A prelaunch news conference will be held after the LRR and is planned for 1 p.m. EDT. The briefing will be broadcast live from the news center at NASA's Kennedy Space Center on NASA TV.

Image above: Technicians completed connections between the LRO and LCROSS spacecraft and the Atlas V rocket at Launch Complex 41 at Cape Canaveral Air Force Station in Florida. Photo credit: NASA/Dimitri Gerondidakis



Mission Overview
NASA's Lunar Reconnaissance Orbiter and Lunar Crater Observation and Sensing Spacecraft will fly to the moon atop the same Atlas V rocket, although they will use vastly different methods to study the lunar environment. LRO will go into orbit around the moon, turning its suite of instruments towards the moon for thorough studies. The spacecraft also will be looking for potential landing sites for astronauts.

LCROSS, on the other hand, will guide an empty upper stage on a collision course with a permanently shaded crater in an effort to kick up evidence of water at the moon's poles. LCROSS itself will also impact the lunar surface during its course of study.

Liftoff currently is scheduled for June 17 at 3:51 p.m. EDT. There are two more launch opportunities that day at 4:01 p.m. and 4:11 p.m.

Additional Resources
› LRO Fact Sheet
› LRO/LCROSS Press Kit
› LRO/LCROSS Launch Coverage Events