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Exploration Of The Moon


Waspie_Dwarf

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At the moment just one, solitary spacecraft, the European Space Agency's Smart-1 is imaging the moon. However over the next few years a flotila of spacecraft from the USA, China and India are due to be launched towards our natural satellite. It seems sensible, therefore, to start a topic along the lines of the Exploration of Mars thread.

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NASA To Crash Impactor into Moon in Water Search

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NASA will send an impactor spacecraft to the moon with the launch of the Lunar Reconnaissance Orbiter, scheduled for October 2008. The Lunar Crater Observation and Sensing Satellite will travel independently of the orbiter and crash into the lunar surface to search for water ice.

Image above: In this artist's concept, the upper stage and a "sheparding spacecraft" (left) approach the moon before impacting at the south pole (right). Credit: NASA/John Frassanito and Associates. + View Animation (Windows)

First, the craft will direct the upper stage used to leave Earth orbit to crash into a permanently-shadowed crater at the lunar south pole, creating a plume visible to Earth-based observatories. Next, the satellite will observe the plume and fly through it using several instruments to look for water. At the end of its mission, the satellite will itself become an impactor, creating a second plume visible to lunar-orbiting spacecraft and Earth-based observatories.

The Lunar Reconnaissance Orbiter is the first of many robotic missions NASA will conduct between 2008 and 2016 to study, map, and learn about the lunar surface as we prepare to return astronauts to the moon. Early missions like this one will help determine potential lunar landing sites and explore whether resources, such as oxygen, hydrogen, and metals, are available.

Robotic missions like this will work in tandem with humans as we chart a new course into the cosmos, laid out in the Vision for Space Exploration announced by President Bush in January 2004. The Vision calls for landing humans on the moon before the end of the next decade, paving the way for eventual journeys to Mars and beyond.

We're well on the way to this goal, with development moving forward on the Crew Exploration Vehicle, the next generation spacecraft which builds on the best of shuttle and Apollo technology.

Source: NASA - The Vision For Space Exploration

Edited by Waspie_Dwarf
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The user posted image press release is reproduced below:

April 10, 2006
Michael Braukus/Dolores Beasley

Headquarters, Washington

(202) 358-1979/1753

John Bluck

Ames Research Center, Moffett Field, Calif.

(650) 604-5026

RELEASE: 06-181

NASA Chooses New Spacecraft to Search for Water on Moon

NASA will send a second spacecraft to the moon with the launch of the Lunar Reconnaissance Orbiter, scheduled for October 2008. The Lunar Crater Observation and Sensing Satellite will travel independent of the orbiter to search for water ice.

The spacecraft, proposed by NASA's Ames Research Center, Moffett Field, Calif., will fly as a secondary payload on the Evolved Expendable Launch Vehicle that will launch the orbiter from NASA's Kennedy Space Center, Fla.

First, the craft will direct the upper stage used to leave Earth orbit to crash into a permanently-shadowed crater at the lunar south pole, creating a plume visible to Earth-based observatories. Next, the satellite will observe the plume and fly through it using several instruments to look for water. Then the satellite will itself become an impactor, creating a second plume visible to lunar-orbiting spacecraft and Earth-based observatories.

"This type of payload is not new to NASA," said Associate Administrator for the Exploration Systems Mission Directorate Scott Horowitz, who made the selection. "We are taking advantage of the payload capability of the launch vehicle to conduct additional high risk/high payoff science to meet Vision for Space Exploration goals. It also signals to our workforce that innovative and competitive, low-cost approaches will be rewarded," he said.

The Lunar Reconnaissance Orbiter is the first of many robotic missions NASA will conduct between 2008 and 2016 to study, map, and learn about the lunar surface to prepare for the return of astronauts to the moon. These early missions will help determine lunar landing sites and whether resources, such as oxygen, hydrogen, and metals, are available for use in NASA's long-term lunar exploration objectives.

NASA's requirements for the secondary payload were that it benefits the robotic lunar program, cost no more than $80 million and not exceed 2,205 pounds (1000 kilograms).

On January 10, 2006, NASA issued a request for information to industry to allow businesses to provide secondary payload concepts to NASA. NASA encouraged its field centers to team with industry to develop proposals. Each NASA center reviewed ideas from industry, as well as secondary payload concepts developed internally. Several proposers, such as the winning spacecraft, took advantage of a new secondary payload adapter developed by the Air Force Research Laboratory, Kirkland Air Force Base, N.M.

NASA asked that the concepts advance the Vision for Space Exploration by advancing lunar science, characterizing the lunar environment, and identifying of sites for future human missions NASA was also looking for missions that would advance commercial opportunities and collect engineering data to support the Constellation program, which is developing NASA's new spaceship, the Crew Exploration Vehicle.

For more about NASA's plans to explore the moon, Mars and beyond, visit:

www.nasa.gov/exploration

- end -

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Source: NASA Press Release 06-181

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Nasa's become quite fond of smashing heavy things into various space objects.

Of course, it's a good idea. So brilliantly simple, and relatively easy to execute.

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Nasa's become quite fond of smashing heavy things into various space objects.

Of course, it's a good idea. So brilliantly simple, and relatively easy to execute.

Not just NASA, ESA too, for the Don Quijote mission is a European idea.

NASA tried this trick before when they smashed Lunar Prospector into a South Polar crater. No water was directly observed but the craft was not made for this purpose and the observations were made from Earth. If the water is actually there then this mission will have a much greater chance of finding it.

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Tectonic β€˜wrinkles’ in Crater De Gasparis

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This image, taken by the Advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows Crater De Gasparis on the Moon.
The AMIE camera obtained this image on 14 January 2006 from a distance of about 1090 kilometres with a ground resolution of approximately 100 metres per pixel. It is located close to the Mare Humorum, at longitude 51.2Β° West and latitude 26.0Β° South, and has a diameter of about 30 kilometres.

Credits: ESA/SPACE-X (Space Exploration Institute)


22 March 2006
This image, taken by the Advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows Crater De Gasparis on the Moon.

The AMIE camera obtained this image on 14 January 2006 from a distance of about 1090 kilometres with a ground resolution of approximately 100 metres per pixel.
Crater De Gasparis is located close to the Mare Humorum, at longitude 51.2Β° West and latitude 26.0Β° South, on the lower left quarter of the Moon’s Earth-facing side. It has a diameter of about 30 kilometres and can be seen with the naked eye from Earth.

The criss-cross patterns in it are called β€˜rilles’ (these are features where the surface has sunk down to form a trench).

These rilles coincide with deep tectonic faults that have been active over a long period of lunar geological evolution. They are the result of stresses due to all the tidal forces and volcanic expansion over the lunar mantle during the last stages of lava flooding of Oceanus Procellarum.

The fact that the rilles cross the crater means that they formed after the crater. This is a good example for how geologists can determine the relative history of the Moon’s surface.

This crater is named after the Italian astronomer Annibale de Gasparis (1819-1892). De Gasparis was director of the observatory in Naples, Italy.

Source: ESA - Smart-1 Edited by Waspie_Dwarf
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SMART-1 maps Humorum edge - where Highlands and Mare mix

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This sequence of images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows an area on the near side of the Moon, at the edge of the Mare Humorum basin.
AMIE obtained these raw images on 13 January 2006 from a distance ranging between 1031 and 1107 kilometres from the surface, with a ground resolution between 93 and 100 metres per pixel.

The imaged area is located at longitude 45.7ΒΊ West and latitude between 30.5ΒΊ and 24.5ΒΊ South. The field of view of each single image is about 50 kilometres.

Credits: ESA/SPACE-X (Space Exploration Institute)


26 April 2006
This sequence of images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows on area on the near side of the Moon, on the edge of the Mare Humorum basin.

AMIE obtained these raw images on 13 January 2006 from a distance ranging between 1031 and 1107 kilometres from the surface, with a ground resolution between 93 and 100 metres per pixel.
The imaged area is located at longitude 45.7ΒΊ West and latitude between 30.5ΒΊ and 24.5ΒΊ South. The field of view of each single image is about 50 kilometres.

The flat lava plain in the upper right image is the floor of Mare Humorum. The bowl-shaped crater on top, cut by a fracture, is called β€˜Liebig F’ and has a diameter of nine kilometres.

The Mare Humorum impact basin is 825 kilometres across. Its precise age could not be determined yet by previous lunar programmes, but geologic mapping suggest it could be around 3.9 thousand million years old – an age comprised between those of the Imbrium and Nectaris Basins. The Humorum basin is filled with a layer of basalt, likely thicker than three kilometres at its centre.

user posted image

This screenshot image, generated by the ESA planning software MAPPS, illustrates the movement of the spacecraft over the lunar surface. In this way it is possible to generate a lunar map with sequences of images taken by the SMART-1's AMIE camera. The tilt of the individual frames is a result of the spacecraft attitude, which is driven by thermal constraints in orbit.
This particular map is built with images taken on 13 January 2006, and refers to an area at the edge of Mare Humorum.

Credits: ESA


The Humorum basin, like several other lunar basins, was formed in a period which ended around 4.1 billion years ago. It was filled with mare material - basaltic flood eruptions caused by very large meteoroid impacts - only during the later Eratosthenian era, in a period comprised between 3.9 and 3.2 billion years ago. The western edge of the sea is marked by a network of cracks and clefts following the Rupes Liebig.

The three northern images include part of the flat darker area corresponding to the mare basalt filling the inner ring of the basin impact. A fresh small crater is surrounded by brighter deposits.

The top north image also shows giant lava tubes or rilles in the Mare. Some graben-lineated structures (a graben is an elongated and relatively depressed crustal block that between two fault systems) indicate the stress structures created during the multi-ring collapse, and refreshed by additional load deformation from the weight of later basalt fill.

It is possible to notice the landscape transition towards the most southern image typical of an old cratered highland. In the middle image the small craters are not very clear because the terrain has been partly covered by material ejected from the impact basin.


Note:

An intersting reference on Mare Humorum compositional and geological studies is given by Martin, Pinet, Chevrel and Daydou (1998, http://www.lpi.usra.edu/meetings/LPSC98/pdf/1547.pdf)

Source: ESA - Smart-1
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SMART-1’s view of Crater Hopmann: on the shoulder of a giant

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This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows one quarter of crater Hopmann - an impact structure about 88 kilometres in diameter.
AMIE obtained this image on 25 January 2006 from a distance of about 840 kilometres from the surface, with a ground resolution of 76 metres per pixel.

The imaged area, not visible from Earth because it is located on the far side of the Moon, is positioned at latitude of 51.7ΒΊ South and longitude 159.2ΒΊ East. It covers a square of about 39 kilometres per side.

Credits: ESA/SPACE-X (Space Exploration Institute)


3 May 2006
This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows one quarter of crater Hopmann - an impact structure about 88 kilometres in diameter.

AMIE obtained this image on 25 January 2006 from a distance of about 840 kilometres from the surface, with a ground resolution of 76 metres per pixel.
The imaged area, not visible from Earth because it is located on the far side of the Moon, is positioned at latitude of 51.7ΒΊ South and longitude 159.2ΒΊ East. It covers a square of about 39 kilometres per side.

The crater (centred at 50.8ΒΊ South, 160.3ΒΊ East) is situated on the edge of the giant South Pole-Aitken basin SPA, the largest impact crater in the solar system with a diameter of 2500 kilometres and a depth of 13 kilometres. The SPA basin shows distinctive chemical composition with unusual mineralogy types, and possible exposure of rocks from the lower crust or the upper mantle.

The hills on the lower left side are the crater wall of Hopmann. This crater is very old - many small craters can be seen on its flat floor, the largest one showing an interesting double-ringed structure. The outer rim has been also eroded by later impacts.

The small crater chains to the left of Hopmann can be interpreted as series of so-called β€˜secondary craters’, created by the impact of the material ejected from a nearby large impact. This ejected material flies away in molten state, and fall in large β€˜droplets’. When these impact on the surface, they form typical crater chains as those visible in this image.

The crater is named after Josef Hopmann (1890-1975), an astronomer that worked in Bonn, Leipzig and as Director of the Vienna Observatory.

Source: ESA - Smart-1
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ISRO and NASA Sign MOU on Chandrayaan-1


The Indian Space Research Organisation (ISRO) press release is reproduced below:

May 9, 2006

Mr G Madhavan Nair, Chairman, ISRO, and Dr Michael Griffin, Administrator, National Aeronautics and Space Administration (NASA) of USA today (May 9, 2006) signed Memoranda of Understanding (MOU) at ISRO Satellite Centre (ISAC), Bangalore, on inclusion of two US Scientific instruments on board India's first mission to Moon, Chandrayaan-1. These instruments are - Mini Synthetic Aperture Radar (Mini SAR) developed by Applied Physics Laboratory, Johns Hopkins University and funded by NASA and Moon Mineralogy Mapper (M3), jointly built by Brown University and Jet Propulsion Laboratory (JPL) of NASA.

user posted image
Mr G Madhavan Nair, Chairman, ISRO (centre) and Dr Michael Griffin, Administrator, NASA (right), signing
MOU on Chandrayaan-1 at ISRO Satellite Centre.


Chandrayaan-1, scheduled during 2007-2008, is India's first unmanned scientific mission to moon. The main objective is the investigation of the distribution of various minerals and chemical elements and high-resolution three-dimensional mapping of the entire lunar surface. ISRO's Polar Satellite Launch Vehicle, PSLV, will launch Chandrayaan-1 into a 240 km X 24,000 km earth orbit. Subsequently, the spacecraft's own propulsion system would be used to place it in a 100 km polar orbit around the moon.

The Indian payloads on board Chandrayaan-1 include: a Terrain Mapping Camera (TMC), a Hyper Spectral Imager (HySI), a High-Energy X-ray spectrometer (HEX), a Lunar Laser Ranging Instrument (LLRI) and a Moon Impact Probe (MIP).

The two US instruments, Mini SAR and M3, were selected on the basis of merit out of 16 firm proposals from all over the world received in response to ISRO's announcement of opportunity. The main objective of Mini SAR is to detect water in the permanently shadowed areas of lunar polar regions. The objective of M3 is the characterisation and mapping of minerals on the lunar surface.

Earlier, three instruments - Chandrayaan-1 Imaging X-Ray Spectrometer (CIXS) from Rutherford Appleton Laboratory, UK, developed with contribution from ISRO Satellite Centre; Near Infra-Red Spectrometer (SIR-2) from Max Planck Institute, Germany; and Sub keV Atom Reflecting Analyser (SARA) from Swedish Institute of Space Physics developed in collaboration with ISRO's Vikram Sarabhai Space Centre -- were selected from the European Space Agency besides a RAdiation DOse Monitor (RADOM) from the Bulgarian Academy of Sciences.

The inclusion of US instruments on Chandrayaan-1 has added fillip to the Indo-US cooperation in the space arena which dates back to the very beginning of the Indian space programme. More recently, the India-US Conference on Space Science, Applications and Commerce held at Bangalore during in June 2004 led to the setting up of a Joint Working Group to enhance the cooperation in civil space between India and USA. The Joint Working Group, comprising representatives of government, academic institutions and industries, had its first meeting in Bangalore in June 2005.

During the signing of MOU today, senior NASA and US Embassy officials and senior officials from ISRO and Ministry of External Affairs were present. Dr Griffin also visited the laboratories at ISAC and interacted with senior scientists. He would also be visiting Vikram Sarabhai Space Centre at Thiruvananthapuram and Satish Dhawan Space Centre SHAR at Sriharikota.


Source: ISRO Press Release
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NASA Agrees to Cooperate With India on Lunar Mission


The user posted image press release is reproduced below:

May 9, 2006
Dean Acosta/Melissa Mathews
Headquarters, Washington
(202) 358-1400/1272

RELEASE: 06-219


NASA Agrees to Cooperate With India on Lunar Mission


NASA will have two scientific instruments on India's maiden voyage to the moon. Tuesday, NASA Administrator Michael Griffin and his counterpart, Indian Space Research Organization Chairman G. Madhavan Nair, signed two Memoranda of Understanding in Bangalore, India, for cooperation on India's Chandrayaan-1 mission.

Griffin is touring Indian Space Research Organization facilities this week. He will visit its satellite development center, launch vehicle production center and launch site.

"It is my hope and belief that as we extend the reach of human civilization throughout the solar system, the United States and India will be partners on many more technically challenging and scientifically rewarding projects," Griffin said at a ceremony in Bangalore. "I very much look forward to the opportunity to see first hand India's impressive space facilities, to meet with your scientists and engineers and to learn more about your remarkable work."

Chandrayaan-1, a lunar orbiter, is expected to launch in late 2007 or early 2008. It is a truly international mission, with payloads from Europe as well as the United States. NASA's contribution includes the Moon Mineralogy Mapper, a NASA Discovery Program mission of opportunity designed to assess mineral resources of the moon. A second NASA instrument, Mini-SAR, will look for ice deposits in the moon's polar regions.

Data from the two instruments will contribute to NASA's increased understanding of the lunar environment as it implements the Vision for Space Exploration, which calls for robotic and human exploration of the moon's surface.

For information about the Vision for Space Exploration, visit:
http://www.nasa.gov/exploration
- end -

--------------------------------------------------------------------------------


Source: NASA Press Release 06-219
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NASA Set to Launch Lunar Reconnaissance Orbiter in 2008


The user posted image press release is reproduced below:

May 18, 2006
Michael Braukus/Dolores Beasley
Headquarters, Washington
(202) 358-1979/1753

Nancy Neal Jones
Goddard Space Flight Center, Greenbelt, Md.
(301) 286-0039

RELEASE: 06-224

NASA Set to Launch Lunar Reconnaissance Orbiter in 2008


After successful completion of its mission confirmation review on Wednesday, May 17, NASA's Lunar Reconnaissance Orbiter project has been given the authority to proceed to the implementation phase.

The confirmation review represents NASA's formal decision for authorizing additional work and sets the project's cost estimate. The mission was deemed to be within budget and on schedule to launch in October 2008.

After a 30-year hiatus, the orbiter represents NASA's first step towards returning humans to the moon. The spacecraft will spend an unprecedented year mapping the moon from an average altitude of approximately 30 miles. It will carry six instruments and one technology demonstration to conduct investigations specifically targeted at preparing for future human exploration.

The orbiter is being built at NASA's Goddard Space Flight Center in Greenbelt, Md. The instruments are being provided by various organizations throughout the U.S. and one in Russia. The instruments will generate a global map of the moon; to determine which potential landing sites are free from hazards; to measure light and temperature patterns at the moon's poles; to search for potential resources, such as water; and to assess the deep-space radiation environment and its potential effects on humans.

The next spacecraft milestone is the critical design review, scheduled for later this year. This review represents the completion of detailed system designs and marks the transition into the manufacturing, assembly, and integration phase of the mission development cycle.

For information about NASA's exploration efforts and the Lunar Reconnaissance Orbiter mission, visit:



For information about NASA and agency programs, visit:

http://www.nasa.gov/home

- end -

--------------------------------------------------------------------------------


Source: NASA Press Release 06-224
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Highlands and Mare landscapes on the Moon

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These two images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESAÒ€ℒs SMART-1 spacecraft, show the difference between lunar highlands (left) and a Γ’β‚¬ΛœmareÒ€ℒ area (right) from close by. Highlands present a very irregular topography and many craters, while the mare area is comparatively flat and shows a much smaller number of craters.
The first image, showing highlands, was obtained by AMIE on 22 January 2006, from a distance of about 1112 kilometres from the surface, with a ground resolution of 100 metres per pixel. The imaged area is centred at a latitude of 26ΒΊ South and at a longitude of 157ΒΊ West.

The second image, showing a mare, was taken on 10 January 2006, from a distance of about 1990 kilometres and with a ground resolution of 180 metres per pixel. The geographical coordinates of the area are 27.4ΒΊ North latitude and 0.8ΒΊ East.

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


26 May 2006
These two images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESAÒ€ℒs SMART-1 spacecraft, show the difference between lunar highlands and a mare area from close by.

The first image, showing highlands, was obtained by AMIE on 22 January 2006, from a distance of about 1112 kilometres from the surface, with a ground resolution of 100 metres per pixel. The imaged area is centred at a latitude of 26ΒΊ South and at a longitude of 157ΒΊ West.
The second image, showing a mare, was taken on 10 January 2006, from a distance of about 1990 kilometres and with a ground resolution of 180 metres per pixel. The geographical coordinates of the area are 27.4ΒΊ North latitude and 0.8ΒΊ East.

Already when looking at the Moon with the naked eye, it can be seen that there are bright and dark areas on its surface. Centuries ago, the dark areas were called 'maria', presumably assuming that the observer would be seeing water oceans. Today we know that there is no liquid water on our satellite. However, telescopic observations showed that the maria are very flat, and are very different from the so-called highlands. The highlands are heavily cratered and mountainous.

We have learned that the maria are relatively young areas on the Moon which were generated after very large impacts penetrated the crust of our Moon and excavated basins. During later volcanic episodes, liquid magma came to the surface and filled these basins. When it cooled down and solidified, it formed the large flat areas we can still see now. As this happened in comparatively recent times, the number of impact craters is far less than in the highland areas.

From the two AMIE images it is possible to see how highlands present a very irregular topography and many craters, while the mare area is comparatively flat and shows a much smaller number of craters.

Source: ESA - Smart-1 Edited by Waspie_Dwarf
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SMART-1 close-up on Zucchius crater’s central peaks

user posted image

This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows the central peaks of crater Zucchius.
AMIE obtained this image on 14 January 2006 from a distance of about 753 kilometres from the surface, with a ground resolution of 68 metres per pixel. The imaged area is centred at a latitude of 61.3ΒΊ South and longitude 50.8ΒΊ West.

Zucchius is a prominent lunar impact crater located near the southwest limb. It has 66 kilometres diameter, but only its inside is visible in this image, as the AMIE field of view is 35 kilometres from this close-up distance.

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


1 June 2006
This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows the central peaks of crater Zucchius.

AMIE obtained this image on 14 January 2006 from a distance of about 753 kilometres from the surface, with a ground resolution of 68 metres per pixel.
The imaged area is centred at a latitude of 61.3ΒΊ South and longitude 50.8ΒΊ West. Zucchius is a prominent lunar impact crater located near the southwest limb. It has 66 kilometres diameter, but only its inside is visible in this image, as the AMIE field of view is 35 kilometres from this close-up distance.

Because of its location, the crater appears oblong-shaped due to foreshortening. It lies just to the south-southwest of Segner crater, and northeast of the much larger Bailly walled-plain. To the southeast is the Bettinus crater, a formation only slightly larger than Zucchius.

Zucchius formed in the Copernican era, a period in the lunar planetary history that goes from 1.2 thousand million years ago to present times. Another example of craters from this period are Copernicus (about 800 milion years old) and Tycho (100 million years old). Craters from the Copernican era show characteristic ejecta ray patterns - as craters age, ejecta rays darken due to weathering by the flowing solar wind.

The hills near the centre of the image are the so-called β€˜central peaks’ of the crater, features that form in large craters on the Moon. The crater is formed by the impact of a small asteroid onto the lunar surface. The surface is molten and, similarly to when a drop of water falls into a full cup of coffee, the hit surface bounces back, it solidifies and then 'freezes' into the central peak.

The name of Zucchius crater is due to the Italian Mathematician and astronomer Niccolo Zucchi (1586-1670).

Source: ESA - Smart-1
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  • 2 weeks later...
A Meteoroid Hits the Moon


June 13, 2006: There's a new crater on the Moon. It's about 14 meters wide, 3 meters deep and precisely one month, eleven days old.

NASA astronomers watched it form: "On May 2, 2006, a meteoroid hit the Moon's Sea of Clouds (Mare Nubium) with 17 billion joules of kinetic energyβ€”that's about the same as 4 tons of TNT," says Bill Cooke, the head of NASA's Meteoroid Environment Office in Huntsville, AL. "The impact created a bright fireball which we video-recorded using a 10-inch telescope."

Lunar impacts have been seen before--"stuff hits the Moon all the time," notes Cooke--but this is the best-ever recording of an explosion in progress:

user posted image
Above: A meteoroid hits the Moon, May 2, 2006, video-recorded by MSFC engineers
Heather McNamara and Danielle Moser. [Larger video] [labels]


The video plays in 7x slow motion; otherwise the explosion would be nearly invisible to the human eye. "The duration of the fireball was only four-tenths of a second," says Cooke. "A student member of our team, Nick Hollon of Villanova University, spotted the flash."

Taking into account the duration of the flash and its brightness (7th magnitude), Cooke was able to estimate the energy of impact, the dimensions of the crater, and the size and speed of the meteoroid. "It was a space rock about 10 inches (25 cm) wide traveling 85,000 mph (38 km/s)," he says.

If a rock like that hit Earth, it would never reach the ground. "Earth's atmosphere protects us," Cooke explains. "A 10-inch meteoroid would disintegrate in mid-air, making a spectacular fireball in the sky but no crater." The Moon is different. Having no atmosphere, it is totally exposed to meteoroids. Even small ones can cause spectacular explosions, spraying debris far and wide.

According to the Vision for Space Exploration, NASA is sending astronauts back to the Moon. Are these meteoroids going to cause a problem?

"That's what we're trying to find out," says Cooke. "No one knows exactly how many meteoroids hit the Moon every day. By monitoring the flashes, we can learn how often and how hard the Moon gets hit."

The work is underway. Using a computerized telescope built by Rob Suggs and Wesley Swift of the Marshall Space Flight Center, Cooke's group is monitoring the night side of the Moon "as often as ten times a month, whenever the lunar phase is between 15% and 50%."

During a telescope test last November 7th, Suggs and Swift recorded an explosion on their very first night of observing. A piece of debris from Comet Encke struck the plains of Mare Imbrium, making a crater about 3 meters wide.

user posted image
Above: The light curve of the May 2nd explosion in
Mare Nubium. [Larger image]


Now that regular monitoring has begun, Cooke's group has already found a second impact, the May 2nd event, in only 20 hours of watching. This time, they believe, the impactor was a random meteoroid, "a sporadic," from no particular comet or asteroid.

"We've made a good beginning," says Cooke, but much work remains. He would like to observe all year long, watching the Moon as it passes in and out of known meteoroid streams. "This would establish a good statistical basis for planning [activities on the Moon]."

Is it safe to go moon walking during a meteor shower? How much shielding does a lunar habitat need? Does the Moon have its own meteor showers, unknown on Earth?

Expect the answers in a flash.


Author: Dr. Tony Phillips | Production Editor: Dr. Tony Phillips | Credit: Science@NASA


More Information

The Sky is Falling -- (Science@NASA) NASA researchers are mining old Apollo seismic data for clues to lunar meteoroid impacts

An Explosion on the Moon -- (Science@NASA) A piece of Comet Encke hit Mare Imbrium; the explosion was visible from Earth

A.L.P.O. Lunar Section: Meteoritics Impact Search -- Lunar meteorite flashes are visible through backyard telescopes. The Association of Lunar and Planetary Observers is helping amateur astronomers get involved in the hunt.


The Vision for Space Exploration

Source: Science@NASA
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SMART-1 manoeuvres prepare for mission end


23 June 2006
After sixteen months orbiting the Moon, ESA's lunar mission is preparing for the end of its scientific exploration. On 19 June, SMART-1 mission controllers initiated a 17-day series of manoeuvres aimed at positioning the spacecraft to enhance science data return as the mission winds down.

user posted image
Artist's impression of SMART-1

Credits: ESA


SMART-1, Europe's successful first Moon mission, is scheduled to end on 3 September 2006, impacting on the Moon's surface in a disposal plan similar to that of many earlier lunar missions and almost three years to the day after its 2003 launch.

The recently started manoeuvre campaign aims to avoid having the spacecraft intersect with the Moon at a disadvantageous time from the scientific point of view, as it would have naturally about 17 August if left alone. Instead, this 'extension' to mission operations will provide new opportunities for low-altitude scientific observations and give optimum science returns during and after the spacecraft's controlled impact on the Moon.
In preparation for mission end, spacecraft controllers at ESOC, ESA's Spacecraft Operations Centre in Darmstadt, Germany, have started a series of thruster firings to give a 'delta-velocity,' or change in velocity, of approximately 12 metres per second. This will raise the orbit perilune (point of closest passage over the Moon) by about 90 kilometres, and will shift the impact to 3 September.

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Computer-generated projection of a possible impact trajectory for SMART-1. The final trajectory has yet to be confirmed.

"The shift in date, time and location for Moon intersection is also optimised to favour scientific observations from Earth," said Gerhard Schwehm, ESA's SMART-1 Mission Manager. "Projections based on the current orbit indicated that the spacecraft, if left as is, would impact the Moon on the far side, away from ground contact and visibility. The new location is on the Moon's near-side, at mid-southern latitudes."

For the manoeuvre campaign, the use of the electric propulsion system (the ion engine) had to be ruled out since all Xenon propellant reserves were exhausted during the mission. The mission control team have instead developed an imaginative approach.


Innovative manoeuvre strategy

"The manoeuvre strategy consists of a series of reaction-wheel off-loadings combined with about three hours of intermittent thrust centred at apolune (point of furthest distance from the Moon) during the next 74 orbits," said Octavio Camino, Spacecraft Operations Manager at ESOC.

The off-loading consists of braking a set of spinning wheels inside the spacecraft, which has the effect of transferring angular momentum from the wheels to the spacecraft and hence changing its velocity.

"We use asymmetric firing of the attitude thrusters to produce a small velocity variation aligned with the flight direction. This will change the orbit by an accumulative effect," added Camino.


"After these manoeuvres, science activities will resume until the impact, with short interruptions for two trim manoeuvres to adjust the impact time, one around the end of July and one at the beginning of September," he concluded.

This manoeuvre campaign and the following trim manoeuvres will make it possible to predict the exact time and location for the SMART-1 impact with more accuracy.


Note

SMART-1 is the first in a series of 'Small Missions for Advanced Research and Technology' in which elements of the platform and miniaturised payload technology have been conceived as a demonstration for future scientific missions and an early opportunity for science. SMART-1 used an innovative ion-propulsion system powered by a small quantity of onboard Xenon and solar energy to generate electricity used to ionise the fuel to travel to the Moon.


After a 27 September 2003 launch, SMART-1 spiralled out over a 14-month period until being captured by the Moon on 15 November 2004, thus successfully achieving the primary objective of demonstrating solar electric propulsion during interplanetary travel. In addition to helping prove new technology from the perspective of satellite design, the mission has also provided an opportunity to develop new ways of conducting ground control operations based on both increased satellite autonomy and improved tools for ground automation.


The wealth of scientific data from SMART-1 are still being processed and analysed. Thanks to SMART-1, scientists all over Europe and around the world will have access to the best-resolution surface images ever taken from lunar orbit, as well as a better knowledge of the Moon's minerals. For the first time from orbit, SMART-1 detected Calcium and Magnesium using an X-ray instrument. It measured compositional changes from the central peaks of craters, volcanic plains and giant impact basins. The camera studied impact craters, volcanic features and lava tubes, and monitored the polar regions.


Source: ESA - News
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Mysterious Lunar Swirls


June 26, 2006: Picture this: A cup of coffee, steaming and black. Add a dollop of milk and gently stir. Eddies of cream go swirling around the cup.

Magnify that image a million times and you've got a Lunar Swirl.

Lunar swirls are strange markings on the Moon that resemble the cream in your coffeeβ€”on a much larger scale. They seem to be curly-cues of pale moondust, twisting and turning across the lunar surface for dozens of miles. Each swirl is utterly flat and protected by a magnetic field.

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Above: The Reiner Gamma swirl, photographed by the ESA's SMART-1 lunar orbiter.[More]


What are they? "We don't know," says Bob Lin of UC Berkeley, who has been studying the swirls for almost 40 years. "These things are very strange."

One of the swirls, Reiner Gamma, can be seen through a backyard telescope. It lies near the western shores of Oceanus Procellarum (the Ocean of Storms) and looks at first sight like a strangely disorganized crater. Indeed, that's what most astronomers thought it was until 1966 when NASA's Lunar Orbiter II spacecraft flew overhead and photographed Reiner Gamma from point blank range. Whatever it was in that grainy black and white photo, it was not a crater.

Before long, two more swirls were found on the Moon's farside. They lie directly opposite the nearside impact basins Mare Imbrium (the Sea of Rains) and Mare Orientale (the Eastern Sea). Impacts on one side of the Moon, it seemed, made swirls on the other side. No one could explain how.

The mystery deepened in 1972 when Lin and colleagues discovered that the swirls were magnetized. "It was an accidental discovery," he recalls. As often happens in science, "we were trying to learn about something completely different."

Their target was Earth's magnetic tail, a ropey pasta of magnetic force fields extending from Earth more than a million miles into deep space. The solar wind blowing against Earth's magnetic field makes the tail, and in the days of Apollo not much was known about it.

To study the tail, "we built two small satellites and asked NASA to put them in orbit around the Moon." The Moon is a great place to sample the Earth's magnetotail, he explains, because the Moon passes through the tail once a month as it orbits Earth.

NASA said yes, and two "sub-satellites" were deployed by the crews of Apollo 15 in 1971 and Apollo 16 in 1972. "The astronauts pushed a button and the satellites were shoved into space by a spring," says Lin. Free of the Service Module (the Apollo mothership), they orbited the Moon, gathering data collected by onboard electron detectors and magnetometers.

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Above: An Apollo sub-satellite leaves the Service Module, an artist's concept. [More]

"We learned a lot about Earth's magnetic tail," says Lin. But they learned even more about the Moon:

As the sub-satellites flew just 60 miles above the lunar terrain, they passed in and out of strange magnetic domains. Magnetic force fields were sprouting out of the lunar surface, reaching up and affecting the satellites' sensors. "We realized that the crust of the Moon must be magnetized," he recalls. It wasn't a global magnetic field like Earth's, but rather a crazy-quilt of magnetic patches.

The strongest fields were located above Lunar Swirls. "The swirls have magnetic fields measuring a few hundred nano-Tesla (nT) at ground level," says Lin. (Earth's magnetic field, for comparison, is 30,000 nT.) "If you walked around a swirl with a magnetic compass, the needle would swing back and forth in a confusing way. You'd quickly get lost because the magnetic fields are so jumbled."

Lin believes these strange fields are an important clue to the origin of swirls, and he offers this possibility:

"Almost four billion years ago, the Moon had a liquid iron core and a global magnetic field. Suppose an asteroid hit the Moon. The blast would make a cloud of electrically conducting gas ('plasma') that would sweep around the Moon, pushing the global magnetic field in front of it. Eventually, the cloud would converge at a point directly opposite the impact, concentrating the magnetic field at that point." Eons later, the Moon's core cooled and its global magnetic field faded away. Only the strongest, tangled patches remained--the swirls.

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Above: A magnetic map of Reiner Gamma obtained by NASA's Lunar Prospector spacecraft in the 1990s. [More]

This idea provides an explanation for the light, creamy appearance of swirls. According to some researchers, moondust is darkened by long exposure to solar wind. Maybe the swirls are light because they get less exposure: their magnetic fields deflect solar wind. If so, lunar swirls are merely a shadow of the magnetic forces arching above them.

It all sounds neat and tidy, but there's a problem: While two of the lunar swirls are directly opposite an impact basin, one is not: Reiner Gamma. The prototype swirl doesn't fit!

"It's a real mystery," acknowledges Lin.

More clues are on the way. NASA is returning to the Moon, eventually with people but first with robot scouts. Leading the way is Lunar Reconnaissance Orbiter (LRO), due to launch in 2008. Among other things, LRO will make detailed 3D maps of the whole Moon using a state-of-the-art camera and a laser. Its view of the swirls should be breathtaking.

Another NASA instrument, the Moon Mineralogy Mapper, is hitching a ride to the Moon onboard India's Chandrayaan-1 spacecraft, also due to launch in 2008. Using an infrared spectrometer, "M-cubed" will survey the lunar terrain and tell us in fantastic detail what minerals are in the ground. The whole Moon will be surveyed--including swirls.

What are swirls made of? Are they truly flat? How does the cream differ from the coffee? Questions to ponder over your next cup of joe….


Author: Dr. Tony Phillips | Production Editor: Dr. Tony Phillips | Credit: Science@NASA


More Information

Lunar swirls, magnetic anomalies and the Reiner Gamma Formation -- by Marvin W. Huddleston

Reiner Gamma swirl: magnetic effect of a cometary impact? -- an alternate explanation for one swirl

Chandrayaan-1 -- India's first mission to the Moon

Lunar Reconnaissance Orbiter -- this robotic scout will survey the Moon to prepapre for future human landings

Lunar Orbiter II -- one of the first spacecraft to obtain up-close images of lunar swirls

Lunar Prospector -- In the 1990s, magnetometers onboard this NASA spacecraft surveyed the Moon, confirming and expanding the results of the Apollo 15 and 16 subsatellites.

Optical Maturity and Magnetic Studies of Lunar Swirls -- by C.G. Hughes et al.

Apollo subsatellites -- facts and figures

The fine scale lunar magnetic field -- a review of Apollo subsatellite measurements


The Vision for Space Exploration

Source: Science@NASA
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Kepler Crater as seen by SMART-1

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This animation, made from images taken by the Advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows Kepler crater on the Moon.
AMIE obtained this sequence on 13 January 2006 from a distance ranging between 1613 and 1702 kilometres from the surface, with a ground resolution between 146 and 154 metres per pixel (the separated images can be downloaded here: AMI_EAE3_001775_00013_00017.JPG;
AMI_EAE3_001775_00014_00017.JPG;
AMI_EAE3_001775_00015_00017.JPG;
AMI_EAE3_001775_00016_00017.JPG;
Kepler;
AMI_EAE3_001775_00018_00017.JPG ).

The imaged area is centred at a latitude of 37.8ΒΊ South and longitude 9.0ΒΊ East. Kepler is a small young crater situated between Oceanus Procellarum and Mare Insularum. It has a diameter of 32 km and it is 2.6 kilometres deep.

This particular sequence of images demonstrates the so called β€˜tracking mode’ of SMART-1 spacecraft, used to track a fixed target when flying over it. To stay within the thermal constraints, the spacecraft had to change its roll during the images acquisition, thus the image is slightly rotated when passing from one frame to the next.

Credits: ESA/Space-X (Space Exploration Institute)


30 June 2006
This animation, made from images taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows Kepler crater on the Moon.

AMIE obtained this sequence on 13 January 2006 from a distance ranging between 1613 and 1702 kilometres from the surface, with a ground resolution between 146 and 154 metres per pixel.
The imaged area is centred at a latitude of 37.8ΒΊ South and longitude 9.0ΒΊ East. Kepler is a small young crater situated between Oceanus Procellarum and Mare Insularum. It has a diameter of 32 km and it is 2.6 kilometres deep.

Kepler displays a ray system that overlaps with rays from other craters and which extends over 300 kilometres. The outer wall shows a slightly polygonal shape. The interior walls of the crater are slumped and slightly terraced, and descend to an uneven floor and a minor central rise.

user posted image

This 3D anaglyph image shows Kepler, a young crater on the Moon. AMIE obtained this sequence on 13 January 2006 from a distance ranging between 1613 and 1702 kilometres from the surface, with a ground resolution between 146 and 154 metres per pixel.
The imaged area is centred at a latitude of 37.8ΒΊ South and longitude 9.0ΒΊ East. Kepler is a small young crater situated between Oceanus Procellarum and Mare Insularum. It has a diameter of 32 km and it is 2.6 kilometres deep.

This image is best viewed with 3D red/green glasses (red on the left eye).

Credits: ESA/Space-X (Space Exploration Institute)


This particular sequence of images demonstrates the so called 'tracking mode' of the SMART-1 spacecraft, used to track a fixed target when flying over it. While flying over Kepler, the clear filter of the camera was always pointed to the same position.

To stay within the thermal constraints, the spacecraft had to change its roll during the images acquisition, thus the image is slightly rotated when passing from one frame to the next.


Thanks to the tracking mode it is possible to obtain information about the size and roughness properties of the soil. It also allows multiple stereo views of the target’s topography.

Kepler crater is named after Johannes Kepler (1571-1630), German astronomer known for his three laws of planetary motion.

Source: ESA - Smart-1
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Gassendi crater - clue on the thermal history of Mare Humorum

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This mosaic of two images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows the inside of crater Gassendi on the Moon.
AMIE obtained these images on 13 January 2006, one minute apart from each other, from a distance of about 1220 kilometres (top frame) and 1196 kilometres (bottom frame) from the surface, with a ground resolution of 110 and 108 metres per pixel, respectively. The separate images can be downloaded here [AMI_EAE3_001775_00012_00020.JPG , AMI_EAE3_001775_00011_00020.JPG ].

The area shown in the top image is centred at a latitude of 16.2ΒΊ South and longitude 40.2ΒΊ West, while the bottom images is centred at a latitude of 17.9ΒΊ South and longitude 40.2ΒΊ West.

The mosaic shows the inside of crater Gassendi, an impact feature located on the near side of the Moon, at the northern edge of Mare Humorum. The crater is actually much larger than the field of view visible in this image. The hills on the lower right of the mosaic are the central peak of the crater, with a height of roughly 1.2 kilometres. The crater almost fully visible on the top is called 'Gassendi A'.

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


6 July 2006
This mosaic of two images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows the inside of crater Gassendi on the Moon.

AMIE obtained these images on 13 January 2006, one minute apart from each other, from a distance of about 1220 kilometres (top frame) and 1196 kilometres (bottom frame) from the surface, with a ground resolution of 110 and 108 metres per pixel, respectively.
The area shown in the top image is centred at a latitude of 16.2ΒΊ South and longitude 40.2ΒΊ West, while the bottom images is centred at a latitude of 17.9ΒΊ South and longitude 40.2ΒΊ West.

Gassendi is an impact feature located on the near side of the Moon, at the northern edge of Mare Humorum. The crater is actually much larger than the field of view visible in this image. The hills on the lower right of the mosaic are the central peak of the crater, with a height of roughly 1.2 kilometres. The crater almost fully visible on the top is called 'Gassendi A'.

Gassendi is a scientifically interesting site because it offers lunar landers the possibility of sampling ancient highland rocks (in the crater's central peak) as well as providing ages for both the Humorum impact basin and the Gassendi crater itself. However, because the terrain just outside the crater is quite rough, if a crew landed in this region, it would be pretty difficult to reach Gassendi's central peaks for sampling. Gassendi was considered as one of the three potential sites for the Apollo 17 mission, that eventually touched ground in the Taurus-Littrow valley.

The age of Gassendi crater is estimated to be about 3.6 thousand million years (with an error of plus or minus 700 million years).

When observed through spectroscopic analysis, crater Gassendi presents a 'behaviour' very different from any other lunar crater (Mikhail 1979). High resolution studies performed in the near-infrared light (Chevrel and Pinet 1990, 1992) indicated the presence of extrusive volcanic material (that is volcanic material flowing out from the surface and then crystallising) limited to the southern portion of Gassendi's floor, which is adjacent to Mare Humorum.

The interpretation of these data suggested that the central part of the crater, including the peak complex, may have a more 'mafic' nature (that is a composition of rocks coming from the solidification of magma which are rich rich in iron and magnesium silicates, such as olivine and pyroxene), with a higher pyroxene component than surrounding highlands.

The data interpretation also suggested that extensive extrusive volcanism may have occurred within the eastern portion of the floor, as also indicated by the significant presence of pyroxene that also corresponds to visible volcanic features. The western part of the crater floor, away from the geometric continuation of the western edge of Mare Humorum, is composed of highlands-rich material.

The difference between the western and eastern side of the Gassendi floor-fractured crater may be strongly linked to the early thermal history of Mare Humorum.

The crater is named after Pierre Gassendi (1592-1655), French philosopher, scientist and mathematician. In 1631, Gassendi became the first person to observe the transit of a planet across the Sun, viewing the transit of Mercury which Kepler had predicted.

Source: ESA - Smart-1
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Mare Humorum: where craters tell the story of basalt

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This mosaic of three images, taken by the advanced Moon Imaging Experiment (AMIE)on board ESA's SMART-1 spacecraft, shows Mare Humorum on the Moon.
AMIE obtained the top frame on 1 January 2006, from a distance of 1087 kilometres from the surface, with a ground resolution of 98 metres per pixel. The remaining two frames were taken on 13 January 2006, from a distance of about 1069 (centre) and 1050 kilometres (bottom) from the surface, with a ground resolution of 97 and 95 metres per pixel, respectively. The separate images can be downloaded here:
AMI_EAE3_001775_00010_00020.JPG ;
AMI_EAE3_001775_00009_00020.JPG ;
AMI_EAE3_001775_00008_00020.JPG;


The area shown in the top image is centred at a latitude of 40.2ΒΊ South and longitude 25.9ΒΊ West; the centre image is centred at a latitude of 40.2ΒΊ South and longitude 27.3ΒΊ West; the bottom image is centred at a latitude of 40.2ΒΊ South and longitude 28.8ΒΊ West.

Mare Humorum, or 'Sea of Moisture', is a small circular mare on the lunar nearside, about 825 kilometres across, filled with a thick layer of mare basalt, (possibly exceeding 3 kilometres in thickness at the centre of the basin). Mare Humorum is a scientifically interesting area because it allows the study of the relationships among lunar mare filling, mare basin tectonics, and global thermal evolution to the major mascon maria – that are regions of the moon's crust which contain a large amount of material denser than average for that area.

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


7 July 2006
This mosaic of three images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows Mare Humorum on the Moon.

AMIE obtained the top frame on 1 January 2006, from a distance of 1087 kilometres from the surface, with a ground resolution of 98 metres per pixel. The remaining two frames were taken on 13 January 2006, from a distance of about 1069 (centre) and 1050 kilometres (bottom) from the surface, with a ground resolution of 97 and 95 metres per pixel, respectively.
The area shown in the top image is centred at a latitude of 40.2ΒΊ South and longitude 25.9ΒΊ West; the centre image is centred at a latitude of 40.2ΒΊ South and longitude 27.3ΒΊ West; the bottom image is centred at a latitude of 40.2ΒΊ South and longitude 28.8ΒΊ West.

Mare Humorum, or 'Sea of Moisture', is a small circular mare on the lunar nearside, about 825 kilometres across. The mountains surrounding it mark the edge of an old impact basin which has been flooded and filled by mare lavas. These lavas also extend past the basin rim in several places. In the upper right are several such flows which extend northwest into southern Oceanus Procellarum.

Mare Humorum was not sampled by the Apollo program, so its precise age could not been determined yet. However, geologic mapping indicates that its age is in between that of the Imbrium and the Nectaris basins, suggesting an age of about 3.9 thousand million years (with an uncertainty of 500 million years).


Humorum is filled with a thick layer of mare basalt, believed to exceed 3 kilometres in thickness at the centre of the basin. On the north edge of Mare Humorum is the large crater Gassendi, which was considered as a possible landing site for Apollo 17.

Mare Humorum is a scientifically interesting area because it allows the study of the relationships among lunar mare filling, mare basin tectonics, and global thermal evolution to the major mascon maria – regions of the moon's crust which contain a large amount of material denser than average for that area (Solomon, Head, 1980).

Past studies (Budney, Lucey) revealed that craters in the mare Humorum sometimes excavate highland material, allowing to estimate the thickness from below the mare cover. Thanks to this, it was also possible to determine that the β€˜multiring’ structure of the Humorum basin has a diameter of 425 kilometres (results based on the US Clementine global topography data).


In general, the chronology of lunar volcanism is based on the analysis of landing site samples from the Apollo and Luna missions, from the study of the relationship between the stratigraphy (layering of deposits) in different regions, and from the analysis of lunar craters – how they degraded over time and how their distribution in number and size varies over the Moon’s surface. From crater statistics, in the year 2000 Hiesinger and colleagues found that in Humorum there was a peak of eruptions at about 3.3-3.5 thousand million years ago.

Source: ESA - Smart-1
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The SMART-1 way - giving the Moon some great new looks


12 July 2006

During its 15-month science mission at the Moon, ESA's SMART-1 returned up to 1000 images per week, whose analysis is still keeping the scientists busy. They show the Moon’s surface in unprecedented detail (with the kind of information that until now, scientists could only dream about) and it is going to get better.

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How three remote-sensing instruments on SMART-1 are scanning the Moon's surface during one pass. Repeated passes will gradually fill in the picture.
SMART-1 is the first of ESA’s Small Missions for Advanced Research in Technology. It headed for the Moon using solar-electric propulsion and carrying a battery of miniaturised instruments.

As well as testing new technology, SMART-1 is making the first comprehensive inventory of key chemical elements in the lunar surface. It is also investigating the theory that the Moon was formed following the violent collision of a smaller planet with Earth, four and a half thousand million years ago.

Credits: ESA - AOES Medialab


When you are studying the Moon there is no such thing as 'point-and-shoot'. The scientists and mission planners on ESA’s SMART-1 lunar explorer had to make sure that when it aimed its camera at a particular lunar feature, there was enough sunlight to illuminate the target. That's no easy task when the spacecraft’s five-hour orbit carried it around the Moon from mid-day to midnight in just a couple of hours.
Not just that, but the SMART-1 team also had to ensure that the spacecraft surveyed as much of the Moon as possible during the mission. "To decipher the formation and evolution of the Moon, and the processes that shape its landscapes, we needed both global coverage and dedicated observations of specific targets," says Bernard Foing, SMART-1 Project Scientist.

To accomplish this heavy load, the mission used a number of innovative observing modes. In all, four styles of observation were used: nadir observations, targeted observations, moon-spot pointing and push-broom observations.


Looking 'nadir'

During SMART-1's first six months, the nominal mission, the emphasis was placed on surveying. Previously, the best digital Moon maps have been from the US Clementine mission, revealing colour details of 200 metres across. At its best, the SMART-1 survey maps reveal features just 40 metres across.

"SMART-1 has produced images for some very detailed maps of the Moon," says David Frew, SMART-1's Science Operations Manager, from ESA's European Space Research and Technology Centre (ESTEC) in The Netherlands.

To achieve the survey, the spacecraft simply pointed its cameras straight down and continuously recorded what passed beneath the spacecraft. Known as nadir observations, this was not as simple as it sounds because of the Sun’s heat on the spacecraft.

user posted image

These views show the coverage of the Moon done by the Advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft during the first part (nominal mission) of lunar observations, in survey (or 'nadir') mode.
The top left panel shows the AMIE coverage during the commissioning phase; the top right panel shows the first coverage at medium-solar elevation; the bottom left panel shows the coverage at high solar elevation; the bottom right one shows the second coverage at medium solar elevation.

Credits: ESA


To keep SMART-1 cool, the spacecraft has a number of 'radiators' on the side panels. On the same panels are the star trackers. These tiny cameras watch the stars, so that SMART-1's orientation and movement can be computed.

If sunlight falls onto these sides, the radiators would not dissipate the excess heat efficiently and the star trackers would stop working if direct sunlight heated them beyond a certain point.


So the spacecraft had to twist during its orbit to keep the sunlight off the side panels. This twisting motion turned the cameras and so the Science Team had to carefully calculate the image times to ensure that the camera recorded every part of the lunar surface.

During the survey mode, the other science instruments were also recording data. For example, the X-ray instrument, D-CIXS collected nearly 10 full maps of the lunar surface. These data will be combined into a single definitive map of the Moon's surface composition. It should help determine whether the Moon formed from the debris of a gigantic collision between the Earth and another planet-sized body during the early history of the Solar System.


Lunar targeting and moon-spot pointing

Towards the end of the six-month nominal mission, the team began to experiment with targeted observations. This involved tilting the spacecraft so that it captured a lunar feature even though the spacecraft did not pass directly over the top of it. This was useful for making the most of the infrared spectrometer, SIR, because it has a small field of view just less than one kilometre across. It allowed SIR to measure mineralogical changes across the central peaks of lunar craters.

The targeted observations became increasingly important throughout the extended mission. The survey mode continued when no special targets where available. During the northern winter phase of the extended mission, SMART-1's orbit carried it towards the dawn-dusk line and so targets directly below the spacecraft were poorly lit. This meant tilting the spacecraft towards the sunlit lunar regions. "The illumination drives the way we observe with SMART-1," says Frew.

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These images provide an example of target observations performed by the Advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft.
The left image shows the areas targeted for observations (overimposed on a Clementine map), while the right image shows the acquired images.

The resulting mosaic, built up over successive orbits, provides a nice view of an area south of the Meton crater.

Credits: ESA/Space-X Space Exploration Institute


Targets were selected from requests made by the instrument science teams. Frew and SMART-1 science operations colleagues used computer simulations of SMART-1's orbit to determine whether the requested observations would be possible. Once they had identified a suitable opportunity to gather the data, the instructions were programmed into SMART-1.

Two types of targeted observation were possible. The simplest were when SMART-1 tilted slightly, so that the instruments would track over the feature. Second were the moon-spot pointings. These were used to keep looking at a specific feature as SMART-1 flew past it. For the moon-spot pointings, SMART-1 had to turn to keep the target in sight. Such observations enable scientists to understand the topography and surface roughness of lunar features because they see them from different angles.


Push-broom

The Science Operations team also used push-broom observations. This technique allowed colour images of the Moon to be made. SMART-1's camera, AMIE, had been constructed so its light-collecting detector was split into four regions. One was clear and the other three had filters to cut out all but certain wavelengths of red and infrared light. In the push-broom mode, the camera would take a continuous series of images with a carefully selected exposure time so that the motion of the spacecraft resulted in the surface features falling into each filter one after the other.

This required keeping the camera pointed exactly in the direction of the spacecraft's travel. Unless the team were careful, sunlight would hit the side panels containing the radiators and star trackers. The team identified a number of times when, although sunlight would strike the panels, the heating this would cause was within tolerable limits.

"The push-broom observations were entirely successful," says Miguel Almeida, a Science Operations Engineer at ESTEC. Now scientists will be able to create contextual maps of surface minerals and, for instance, search for glassy areas on the lunar surface, betraying meteorite strikes that have melted small areas.

user posted image

The AMIE camera on board SMART-1 has three fixed-mounted filters which see the Moon in different colour bands. The figure shows four consecutive images taken by AMIE from left to right. The fixed filters are indicated by coloured frames. The images, taken only a few seconds apart, show how the surface is moving through the different filters.

Credits: AMIE Team


Scientist are now preparing for the final phase of the mission, a series of increasingly low altitude orbits that will allow scientists to take their closest look of the entire mission. In particular, they want to study the south pole to see if there are any possible landing sites for future missions. "When you get close, areas that look smooth are actually very rough," says Almeida.

"SMART-1 will help to pinpoint interesting and safe terrains for future exploration," says Foing, "We are using our data and operational experience to contribute to the next generation of international lunar orbiters and landers".

Eventually, the decreasing orbit will run SMART-1 into the Moon, ending the mission in a small impact that will leave behind just a small crater of a few metres size: a little tribute to a highly successful mission.

Source: ESA - Smart-1
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SMART-1 view of crater Sulpicius Gallus

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This mosaic of three images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows the area around the Sulpicius Gallus crater (upper left), a fairly fresh, bowl-shaped crater with a diameter of roughly 12 kilometres, on the near side of the Moon.
AMIE obtained this sequence on 18 March 2006, from a distance of 1200 kilometres from the surface, with a ground resolution ranging from 110 to 114 metres per pixel.The separate images can be downloaded here: [ AMI_EAE3_002083_00005_00016_H.JPG, AMI_EAE3_002083_00004_00015_H.JPG, AMI_EAE3_002083_00005_00015_H.JPG]

The area shown in the top image is centred at a latitude of 19.7ΒΊ North and longitude 12.2ΒΊ East; the image in the middle is centred at a latitude of 18.2ΒΊ North and longitude 12.3ΒΊ East; the bottom image is centred at a latitude of 16.7ΒΊ North and longitude 12.5ΒΊ East.

The area around Sulpicius Crater is geologically interesting for lunar scientists, since it is one of the areas where good spectroscopic data (that is relative to the mineralogical composition) are available both from the Clementine mission and from ground-based observations. These data sets, together with the colour images from the AMIE camera, are helping to better constrain the geological evolution of our closest cosmic neighbour.

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


12 July 2006
This mosaic of three images, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows the area close to the Sulpicius Gallus crater on the Moon.

AMIE obtained this sequence on 18 March 2006, from a distance of 1200 kilometres from the surface, with a ground resolution ranging from 110 to 114 metres per pixel.
The area shown in the top image is centred at a latitude of 19.7ΒΊ North and longitude 12.2ΒΊ East; the image in the middle is centred at a latitude of 18.2ΒΊ North and longitude 12.3ΒΊ East; the bottom image is centred at a latitude of 16.7ΒΊ North and longitude 12.5ΒΊ East.

The prominent crater on the upper left area of this mosaic is called Sulpicius Gallus. It is a fairly fresh, bowl-shaped crater with a diameter of roughly 12 kilometres. The flat lava plains surrounding it belong to the Mare Serenitatis (the 'Sea of Serenity') on the north-eastern side of the Moon facing Earth. The mountains going diagonally through the middle part of the mosaic are called Montes Haemus. They are denoting the edge of the huge impact crater which formed the Mare Serenitatis.

The area around Sulpicius Crater is very interesting for lunar scientists – it is one of the most geologically and compositionally complex areas of the nearside of the Moon. The geologic history of this region has been shaped by impacts of different scales and epochs, by volcanism of variable style and composition with time, and by limited tectonics. Specific findings (Bell and Hawke, 1995) include the detection of relatively fresh highlands materials in the crater.


Good spectroscopic data (that is relative to the mineralogical composition) are available both from the Clementine mission and from ground-based observations, allowing to better constrain the geological evolution of our closest cosmic neighbour.

The area has been suggested to contain mixtures of glassy and black beads generated when large impacts melted part of the lunar surface. However, modelling the spectral properties of material similar to lunar material does not allow to unambiguously match the composition of the material to the measured data.

Colour observations of the AMIE camera will help in further clarifying these issues. So, the combination of high spatial resolution imaging and high spectral resolution spectroscopy from datasets from SMART-1, Clementine and ground based telescopes will finally allow to better model mineral mixtures on the Moon.

user posted image

This 3D anaglyph image shows the area around the Sulpicius Gallus, a fairly fresh, bowl-shaped crater with a diameter of roughly 12 kilometres, on the near side of the Moon.
The stereo anaglyph view is composed from the set of images taken on 18 March 2006 (orbit 2083) and another one of the same area taken on the same day, two orbits or about 10 hours later (orbit 2085), from 1200 kilometres altitude.

The area shown in the top image is centred at a latitude of 19.7ΒΊ North and longitude 12.2ΒΊ East; the image in the middle is centred at a latitude of 18.2ΒΊ North and longitude 12.3ΒΊ East; the bottom image is centred at a latitude of 16.7ΒΊ North and longitude 12.5ΒΊ East.

This image is best viewed with 3D red/green glasses (red on the left eye).

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


The stereo anaglyph view is composed from the set of images taken on 18 March 2006 (orbit 2083) and another one of the same area taken on the same day, two orbits or about 10 hours later (orbit 2085), from 1200 kilometres altitude.

The crater Sulpicius Gallus is named after a Roman general, state man and orator. He is famous for having predicted an eclipse of the moon on the night before the battle of Pydna (168 BC). A man of great learning, in his later years he devoted himself to the study of astronomy.

Source: ESA - Smart-1
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Landscapes from the ancient and eroded lunar far side

IPB Image

This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows a highly eroded highland area close to the equator on the lunar far side - the side of the Moon always facing away from Earth.
AMIE obtained this image on 1 January 2006, from a distance of 1483 kilometres from the surface, with a ground resolution of 134 metres per pixel. The imaged area is centred at a latitude of 4.2ΒΊ South and longitude 98.4ΒΊ East.

This image shows some highly eroded highland areas. Many craters are almost not longer visible, as they were destroyed by subsequent impacts.

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


14 July 2006
This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows a highly eroded highland area on the lunar far side, close to the equator.

AMIE obtained this image on 1 January 2006, from a distance of 1483 kilometres from the surface, with a ground resolution of 134 metres per pixel. The imaged area is centred at a latitude of 4.2ΒΊ South and longitude 98.4ΒΊ East.
The Moon's rotation is locked to the Earth, that is the Moon always presents roughly the same side to the Earth. We call the side facing the Earth the β€˜near side’, while the side facing away is the β€˜far side’.

After the first lunar missions orbited the Moon, it was discovered that unlike the near side, the far side is lacking large lava plains, the so-called β€˜maria’. The far side is mainly composed of heavily cratered highlands, while only very small areas contain smooth lava plains.

The reason for this difference between near side and far side is not exactly understood. Could the tidal pull of the Earth on the Moon - just like the Moon introduces tides on the water bodies of the Earth - have resulted in such a difference?

The modelling of previous topography and gravity measurements indicate that the solid crust is thinner on the near side. As a consequence, large impacts could excavate the crust more easily on the near side, and so lava had an easier way to flow out and create maria formations.

This image shows some highly eroded highland area on the lunar far side. Many craters are almost not longer visible, as they were destroyed by subsequent impacts.

Source: ESA - Smart-1
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Gruithuisen: non-mare volcanism in Procellarum

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This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows the Gruithuisen area on the Moon.
AMIE obtained this sequence on 1 January 2006, from a distance of about 2154 kilometres from the surface, with a ground resolution of 195 metres per pixel. The area shown in the image is centred at a latitude of 34.8ΒΊ North and longitude 40ΒΊ West.

The prominent bowl-shaped crater close to the left edge of the image is Gruithuisen B. Gruithuisen itself is just visible at the right edge of the image. The mountains visible in the area are called Mons Gruithuisen. It is possible to note the large number of similar sized craters to the right of the centre of the image. They are so-called secondary craters, produced by ejecta particles from a large impact which fell back to the Moon.

Credits: ESA/SMART-1/Space-X (Space Exploration Institute)


18 July 2006
This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA's SMART-1 spacecraft, shows the Gruithuisen area on the Moon.

AMIE obtained this sequence on 1 January 2006, from a distance of about 2154 kilometres from the surface, with a ground resolution of 195 metres per pixel. The area shown in the image is centred at a latitude of 34.8 ΒΊ North and longitude 40ΒΊ West.
The prominent bowl-shaped crater close to the left edge of the image is Gruithuisen B. Gruithuisen itself is just visible at the right edge of the image. The mountains visible in the area are called Mons Gruithuisen.

It is possible to note the large number of similar sized craters to the right of the centre of the image. They are so-called secondary craters, produced by ejecta particles from a large impact which fell back to the Moon.

According to Head and Mc Cord (1978), the Gruithuisen dome on the Moon represents volcanic features of Imbrian age which are different in shape and in 'spectral fingerprints' (mineralogical nature). These features are not of a 'mare' nature (a mare is a large lava plain) and they are of 'extrusive' origin, that is, they are generated by volcanic material flowing out from the surface and then crystallising.

The composition, morphology, and age relationships of the domes indicate that the non-mare extrusive volcanism in the northern Procellarum region of the Moon continued until about 3.3 to 3.6 thousand million years ago and was partially contemporaneous with the emplacement of the main sequence of mare deposits.

In 1999 Chevrel, Pinet and Head found that spectral characteristics of the dome and the dome-like unit are clearly different from those of highlands and of the surrounding mare basalts. The spectral identification of a widespread dome-like unit suggests that the specific style of eruption deduced for the formation of the domes (that is, viscous flows of possible more silica composition) might have occurred on a regional scale in this part of the Moon, prior to the Iridum event about 3.8 thousand million years ago. This volcanic style appears to be more widespread in the early part of lunar history than previously thought.

The area is named after Franz von Gruithuisen, a 19th century German astronomer (1774 - 1852). Gruithuisen spent a lot of his time observing the Moon and actually thought it is inhabited. Already in 1840 he proposed that the lunar craters are the result of meteoritic impacts rather than volcanoes, as was commonly believed up into the 20th century.

Source: ESA - Smart-1
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SMART-1 manoeuvres bring Moon impact to nearside


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This artist's impression shows the trajectory of ESA SMART-1 spacecraft in the final phase of its mission, due to end through a small impact on the lunar surface.
After two weeks of manoeuvres started on 19 June and concluded on 2 July 2006, the impact is now set to occur on the near side and most probably at 05:41 UT (07:41 CEST) on 3 September 2006.

Credits: ESA - C.Carreau


19 July 2006
On 2 July 2006, mission controllers successfully completed a two-week manoeuvre campaign designed to adjust the orbit for a nearside impact, to maximise science returns at mission end.

On 19 June, SMART-1 mission controllers at ESOC, ESA's Spacecraft Operations Centre in Darmstadt, Germany, initiated a two-week series of thruster firings aimed at optimising the time and location of impact on the Moon's surface. Disposal via impact is a method adopted by many previous missions and will provide an opportunity to gather science results related to impact effects.
The recently completed manoeuvres comprised 520 reaction-wheel off-loadings using the attitude thruster during 66 orbits, fewer than the 74 orbits initially planned. 'Off loading the reaction wheels' involves using a set of wheels spinning inside the spacecraft together with thruster firings to effect a change in momentum, and hence the velocity, of the spacecraft.

The resulting accumulative change in velocity has shifted the time and location of impact, which, before the manoeuvres, was due to occur in mid-August on the lunar farside; impact is now set to occur on the near side and most probably at 05:41 UT (07:41 CEST) on 3 September 2006.

"Mission controllers and flight dynamics engineers are analysing the results of the manoeuvre campaign to confirm and refine this estimate," says Octavio Camino-Ramos, SMART-1 spacecraft operations manager (SOM) at ESOC, adding, "adjustment manoeuvres are planned on 27 and 28 July, 25 August and on 1 and 2 September."

The manoeuvre just concluded, and the definition of the SMART-1 trajectory, also provide an important piece information for the professional and amateur observers worldwide willing to perform coordinated lunar observations with SMART-1 and to participate in observing the spacecraft's impact.

"We are calling upon astronomical observatories and amateurs worldwide to participate in a coordinated observation effort with SMART-1, including the final orbits until impact," says Bernard Foing, SMART-1 Project Scientist. He adds that, "In the orbits prior to the expected impact, between 19:40 UT (21:40 CEST) on 2 September and 00:40 UT (02:40 CEST) on 3 September, the spacecraft will pass less than 2 kilometres above the lunar surface - based on the known lunar topography - and there is still a possibility of premature impact if some unknown peaks are in the way."


Note

SMART-1 is the first in a series of 'Small Missions for Advance Research and Technology' in which elements of the platform and payload technology have been conceived as a demonstration for future cornerstone missions and an early opportunity for science. SMART-1 uses an innovative ion propulsion system powered by a small quantity of onboard fuel and solar energy, which is used to generate electricity to ionise the fuel.

After its 27 September 2003 launch, SMART-1 spiralled out over a 14-month period until being captured by the Moon on 15 November 2004, thus successfully achieving the primary objective of demonstrating solar electric propulsion. In addition to helping prove new technology from the perspective of the satellite design, the mission has also provided an opportunity to develop new ways of conducting ground control operations based on both increased satellite autonomy and improved ground tools for automation.


Source: ESA - Smart-1 Edited by Waspie_Dwarf
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SMART-1 birthday postcard of Apollo 11 landing site

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This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows the Apollo 11 landing site in the Mare Tranquillitatis on the Moon.
AMIE obtained the image on 5 February 2006 from a distance of 1764 kilometres from the surface, with a ground resolution of 159 metres per pixel. The imaged area is centred at a longitude of 23.9ΒΊ East close to the Moon equator, at 1.7ΒΊ latitude. A 'clean' version of the image can be downloaded here (1888_40C_hi.TIF).

The area is close to crater Moltke (outside the field of view of this image) in the Mare Tranquilitatis. The arrow shows the landing site of Apollo 11, where the first men from Earth set foot on another object in our solar system on 20 July 1969. The two prominent craters nearby are named after two of the Apollo 11 astronauts. The first man on the Moon, Armstrong, has a crater named after him outside the field of this image.

Credits: ESA/Space-X (Space Exploration Institute)


20 July 2006
This image, taken by the advanced Moon Imaging Experiment (AMIE) on board ESA’s SMART-1 spacecraft, shows the Apollo 11 landing site in the Mare Tranquillitatis on the Moon.

AMIE obtained the image on 5 February 2006 from a distance of 1764 kilometres from the surface, with a ground resolution of 159 metres per pixel. The imaged area is centred at a longitude of 23.9ΒΊ East close to the Moon equator, at 1.7ΒΊ latitude.
The area is close to crater Moltke (outside the field of view of this image) in the Mare Tranquilitatis. The arrow shows the landing site of Apollo 11, where the first men from Earth set foot on another object in our solar system on 20 July 1969. The two prominent craters nearby are named after two of the Apollo 11 astronauts. The first man on the Moon, Armstrong, has a crater named after him outside the field of this image.

As can be seen from the image, the area which was selected for the first landing has a fairly featureless, on a large scale smooth surface. This was done on purpose to make the landing easier.

The landing sites of the Apollo missions are important calibration targets for lunar remote sensing missions, as these are the places from where material was brought back to Earth and analysed in detail. The age of the rocks returned with Apollo can be determined with radioisotopic dating methods to very high accuracy and give 'reference points' to remote sensing instruments.

"From SMART-1 observations of previous landing sites we can compare remote observations to the ground truth, and expand from local to global views of the Moon," says Bernard Foing, ESA’s SMART-1 Project scientist. "And we can better define potential sites for future landers," he concluded. This image is a mosaic of several filter images of AMIE, the boundaries of which can be seen by thin horizontal lines (north is up).


Note

The SMART-1 team is also contributing its experience and data set for the upcoming fleet of lunar orbiters and landers. This is being discussed with international partners at the COSPAR Committee for Space Research assembly taking place this week at Beijing, China, 37 years after the historical landing in Mare Tranquillitatis, and on 23-27 July, during an ILEWG (International Lunar Explorer Working Group) international conference on exploration and utilisation of the Moon, also taking place at Beijing.

Source: ESA - Smart-1
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European and worldwide radio telescopes listen to SMART-1

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The Westerbork radio station in the Netherlands, consisting of 14 dish-shaped antennas, 25 metres in diameter each, is one of the most powerful radio observatories in the world. Part of the European Very Large Based Interferometry (VLBI) network of radio telescopes, Westerbork and other European radio stations have been used to track the SMART-1 spacecraft in its orbit around the Moon in a test campaign conducted in May 2006. The same network of telescopes will now track SMART-1 until the end of its mission, due to take place through a small lunar impact on 3 September 2006.

Credits: ASTRON Nico Vermaas - Harm Jan Stiepel


21 July 2006
In Spring this year European radio astronomers started a test observation campaign to track from Earth the trajectory of the SMART-1 spacecraft around the Moon. While other worldwide radio telescopes are now joining the campaign, the experts have started analysing the first results, precious for tracking SMART-1 up to its lunar impact and future lunar missions as well.

The campaign started on 25 May 2006, when European radio astronomers led by Dr Leonid Gurvits, from the Joint Institute for VLBI (Very Long Baseline Interferometry) in Europe (JIVE) in the Netherlands, started the spacecraft observation campaign in coordination with the ESA SMART-1 team.
The 8-hour long observing session involved three European radio telescopes - the Medicina station close to Bologna, Italy, the MetsΓ€hovi station in KylmΓ€lΓ€, Finland, and the Westerbork Radio Observatory at Hooghalen in The Netherlands. In particular, the Medicina station detected SMART-1 in real time, as the telescope is equipped with a real-time spectrum analyser. Further tests were also performed at Westerbork on 17 July 2006.

The test campaign proved to be very successful, and it confirmed that radio observations prior and during the SMART-1 impact are technically feasible and now fully tested with the VLBI setup.

In the meantime, a group of Chinese radio telescopes, under coordination of the Shangaii Astronomical Observatory and in collaboration with the ESA SMART-1 and the JIVE VLBI teams, have also detected and tracked the SMART-1 spacecraft. This will help the Chinese group to validate the ground stations to be used for the Chinese Chang'E1 lunar orbiter, due for launch in 2007.

Two radio telescopes in South America - TIGO station in Chile and the Fortaleza station in Brazil have also agreed to join the club of Smart-1 radio observers. Their participation is extremely valuable as they are located most favourably to conduct the observation just before and during the impact.

Under the coordination of JIVE , also the SMART-1 observing test using TIGO and Fortaleza on 15 and 16 June 2006 was successful, with the spacecraft radio signal clearly detected at both stations. The data arrived to JIVE for further analysis. "This test proves that the setup and scheduling procedure for telescopes never before involved in this kind of observations and based on our earlier test run with the European antennas is correct" says Leonid Gurvits, leader of the JIVE team.

Indeed for both TIGO and Fortaleza this was the first experience in tracking a spacecraft. In particular, the two stations will take advantage of their favourable location to observe the SMART-1 impact, due to take place on 3 September 2006 between 02:00 and 08:00 (CEST).

"It is exciting that worldwide radio telescopes can listen to SMART-1 until impact", says Bernard Foing, SMART-1 Project Scientist. The impact is due to take place on 3 September 2006 at 07:41 CEST (05:41 UT), with an uncertainty of plus or minus 7 hours. "This also proves that SMART-1 is helping to prepare ground stations, radio telescopes and VLBI experiments for future international lunar and planetary missions".

Note

The Chinese radio telescopes team (coordinated by the Shangaii Astronomical Observatory) and the JIVE teams closely collaborate on the Lunar VLBI project, in particular under the joint programme supported by the Royal Dutch Academy of Science (KNAW) and the Chinese Academy of Sciences (CAS).

Source: ESA - Smart-1
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