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Showing posts with label MARS CURIOSITY ROVER. Show all posts
Showing posts with label MARS CURIOSITY ROVER. Show all posts
Monday, February 16, 2015
Monday, December 10, 2012
SAM ON MARS
FROM: NASA
Sample Analysis at Mars (SAM) suite on Mars Curiosity
How samples are delivered and then tested in the Sample Analysis at Mars (SAM) suite on the Mars Curiosity rover.
Sample Analysis at Mars (SAM) suite on Mars Curiosity
How samples are delivered and then tested in the Sample Analysis at Mars (SAM) suite on the Mars Curiosity rover.
Monday, October 15, 2012
Monday, September 3, 2012
MARS-TRACK
FROM: NASA
Looking Back at Tracks from Sol 24 Drive
NASA's Mars rover Curiosity drove about 70 feet (about 21 meters) on the mission's 21st Martian day, or sol (Aug. 30, 2012) and then took images with its Navigation Camera that are combined into this scene, which inclues the fresh tracks. The view is centered toward the west-northwest.
Image credit, NASA-JPL-Caltech
Looking Back at Tracks from Sol 24 Drive
NASA's Mars rover Curiosity drove about 70 feet (about 21 meters) on the mission's 21st Martian day, or sol (Aug. 30, 2012) and then took images with its Navigation Camera that are combined into this scene, which inclues the fresh tracks. The view is centered toward the west-northwest.
Image credit, NASA-JPL-Caltech
Saturday, August 18, 2012
CURIOSITY LASER READIES FOR MARTIAN TARGETS
FROM: LOS ALAMOS NATIONAL LABORATORY
RIGHT: Chem Cam Calibration PreLaunch. PHOTO CREDIT: Los Alamos National Laboratory
ChemCam Laser Sets its Sights on First Martian Target
Rock zapper ready after beaming back images of calibration targets
LOS ALAMOS, NEW MEXICO, August 17, 2012—Members of the Mars Science Laboratory Curiosity rover ChemCam team have received the first photos from the instrument’s remote micro imager. The successful capture of ChemCam’s first 10 photos sets the stage for the first test bursts of the instrument’s rock-zapping laser in the near future.
"The successful delivery of these photos means we can begin efforts in earnest for the first images of Mars rocks by the ChemCam instrument and the first use of the instrument’s laser," said Los Alamos National Laboratory planetary scientist Roger Wiens, Principal Investigator of the ChemCam Team. "We anticipate these next steps over the weekend."
The next tasks for ChemCam—the inaugural laser burst and spectral reading—will help scientists determine the integrity of the ChemCam system and the pointing capability of the rover’s mast, which supports ChemCam’s laser and telescope. Scientists and engineers from NASA’s Curiosity rover mission have selected ChemCam’s first target, a three-inch rock designated N-165 located near the rover.
"Rock N-165 looks like your typical Mars rock, about three inches (seven centimeters) wide and it's about 10 feet away," Wiens said. "We are going to hit it with 14 milliJoules of energy 30 times in 10 seconds. It is not only going to be an excellent test of our system, but it should be pretty cool too."
The ChemCam system is one of 10 instruments mounted on the MSL mission’s Curiosity rover—a six-wheeled mobile laboratory that will roam more than 12 miles of the planet’s surface during the course of one Martian year (98 Earth weeks).
When ChemCam fires its extremely powerful laser pulse, it briefly focuses the energy of a million light bulbs onto an area the size of a pinhead. The laser blast vaporizes a small amount of its target up to seven meters (23 feet) away.
The resultant flash of glowing plasma is viewed by the system’s 4.3-inch aperture telescope, which sends the light down an optical fiber to a spectrometer located in the body of the rover. There the colors of the light from the flash are recorded, enabling scientists to determine the elemental composition of the vaporized material. ChemCam also has a high-resolution camera that provides close-up images of an analyzed location. It can image a human hair from seven feet away.
The ChemCam system is designed to capture as many as 14,000 observations throughout the mission.
The laser, telescope, and camera were provided by the French space agency, CNES, while the spectrometers, electronics, and software were built at Los Alamos National Laboratory, which leads the investigation. The spectrometers were developed with the aid of Ocean Optics, Incorporated, and Jet Propulsion Laboratory assisted with various aspects of development.
RIGHT: Chem Cam Calibration PreLaunch. PHOTO CREDIT: Los Alamos National Laboratory
ChemCam Laser Sets its Sights on First Martian Target
Rock zapper ready after beaming back images of calibration targets
LOS ALAMOS, NEW MEXICO, August 17, 2012—Members of the Mars Science Laboratory Curiosity rover ChemCam team have received the first photos from the instrument’s remote micro imager. The successful capture of ChemCam’s first 10 photos sets the stage for the first test bursts of the instrument’s rock-zapping laser in the near future.
"The successful delivery of these photos means we can begin efforts in earnest for the first images of Mars rocks by the ChemCam instrument and the first use of the instrument’s laser," said Los Alamos National Laboratory planetary scientist Roger Wiens, Principal Investigator of the ChemCam Team. "We anticipate these next steps over the weekend."
The next tasks for ChemCam—the inaugural laser burst and spectral reading—will help scientists determine the integrity of the ChemCam system and the pointing capability of the rover’s mast, which supports ChemCam’s laser and telescope. Scientists and engineers from NASA’s Curiosity rover mission have selected ChemCam’s first target, a three-inch rock designated N-165 located near the rover.
"Rock N-165 looks like your typical Mars rock, about three inches (seven centimeters) wide and it's about 10 feet away," Wiens said. "We are going to hit it with 14 milliJoules of energy 30 times in 10 seconds. It is not only going to be an excellent test of our system, but it should be pretty cool too."
The ChemCam system is one of 10 instruments mounted on the MSL mission’s Curiosity rover—a six-wheeled mobile laboratory that will roam more than 12 miles of the planet’s surface during the course of one Martian year (98 Earth weeks).
When ChemCam fires its extremely powerful laser pulse, it briefly focuses the energy of a million light bulbs onto an area the size of a pinhead. The laser blast vaporizes a small amount of its target up to seven meters (23 feet) away.
The resultant flash of glowing plasma is viewed by the system’s 4.3-inch aperture telescope, which sends the light down an optical fiber to a spectrometer located in the body of the rover. There the colors of the light from the flash are recorded, enabling scientists to determine the elemental composition of the vaporized material. ChemCam also has a high-resolution camera that provides close-up images of an analyzed location. It can image a human hair from seven feet away.
The ChemCam system is designed to capture as many as 14,000 observations throughout the mission.
The laser, telescope, and camera were provided by the French space agency, CNES, while the spectrometers, electronics, and software were built at Los Alamos National Laboratory, which leads the investigation. The spectrometers were developed with the aid of Ocean Optics, Incorporated, and Jet Propulsion Laboratory assisted with various aspects of development.
Sunday, August 12, 2012
MARS CURIOSITY ROVER BEGINS OPERATIONS
FROM: NASA
NASA.gov - Curiosity Rover Update - Surface Operations Begin
VIEW VIDEOhttp://www.nasa.gov/multimedia/videogallery/index.html?media_id=150215811
NASA.gov - Curiosity Rover Update - Surface Operations Begin
VIEW VIDEOhttp://www.nasa.gov/multimedia/videogallery/index.html?media_id=150215811
Monday, August 6, 2012
TO ALL MARTIANS: WE COME IN PEACE TO BLAST YOUR PLANET WITH A LASER
Image credit: NASA/JPL-Caltech
FROM: LOS ALAMOS NATIONAL LABORATORY
Los Alamos Laser Instrument Arrives on Red Planet’s Surface
LANL ChemCam to be tested soon and will begin probing Mars mysteries
LOS ALAMOS, NEW MEXICO, August 6, 2012—Los Alamos National Laboratory scientists are elated by Sunday’s successful landing of NASA’s Curiosity rover on Mars, and are ready to begin a nearly two-year-long mission that will use a rock-zapping laser device mounted on the mast of the SUV-sized rover to help unravel mysteries of the Red Planet. The ChemCam laser characterization instrument was developed at LANL and the French space institute, IRAP.
"I can’t describe the feeling when we realized that Curiosity had landed safely on the planet," said LANL planetary scientist Roger Wiens, principal investigator of the Mars Science Laboratory mission’s ChemCam team. "My own curiosity about Mars began when I was a boy, and having an instrument that I’ve handled land on the Martian surface fulfills a lifelong dream that started long ago with a backyard telescope. This is an extremely happy, fulfilling moment."
The ChemCam system is one of 10 instruments mounted on the MSL mission’s Curiosity rover—a six-wheeled mobile laboratory that will roam more than 12 miles of the planet’s surface during the course of one Martian year (98 Earth weeks). When ChemCam fires its extremely powerful laser pulse, it briefly focuses the energy of a million light bulbs onto an area the size of a pinhead. The laser blast vaporizes part of its target up to seven meters (23 feet) away.
The resultant flash of glowing plasma is viewed by the system’s 4.3-inch aperture telescope, which records the colors of light within the flash. These spectral colors are then interpreted by a spectrometer, enabling scientists to determine the elemental composition of the vaporized material. ChemCam also has a high-resolution camera that provides close-up images of an analyzed location. It can image a human hair from seven feet away.
The core ChemCam team is comprised of Los Alamos National Laboratory researchers and scientists from IRAP, a partner institution in Toulouse, France. Scientists from around the U.S., France, Canada, and the United Kingdom, along with post-doctoral researchers and students from LANL, round out the entire 45-person team.
Sometime around August 10 (sol 4 in Martian days after landing), the ChemCam team expects to take images of calibration targets mounted on the Rover. These initial tests will help scientists determine the integrity of the ChemCam system and the pointing capability of the rover’s mast, which supports ChemCam’s laser and telescope.
The ChemCam instrument is the first to perform active remote sensing on the surface of the Red Planet. It can deliver three laser pulses each second to a single area, or it can quickly zap multiple areas, providing researchers with great versatility for sampling the surface of the planet. The first few laser pulses remove dust that would otherwise obscure the target surface, enabling scientists to observe the underlying sample. In that sense, the laser is like a long arm that can reach out more than twenty feet and brush off a sample before analysis.
The laser can profile through and study surface coatings on rocks, which, Earth scientists have learned, can often provide important clues to climate and water interaction, and can indicate biological interaction with surface materials. ChemCam is designed to look for lighter elements such as hydrogen, carbon, nitrogen, and oxygen, all of which are crucial for life, as well as to determine abundances of other elements.
After firing its laser, the ChemCam system looks at the entire visible spectrum as well as portions on either side (the infrared and ultraviolet), which gives the instrument the ability to see any element in the periodic table. Researchers expect to take the first analyses of the Martian surface sometime on or after sol 11 or 12 (August 17-18). The system is designed to capture as many as 14,000 observations throughout the mission.
Curiosity is expected to investigate the Gale Crater located close to the equator near the boundary between the southern highlands and the more featureless northern low plains of Mars. The massive crater spans 96 miles in diameter, an area roughly equivalent to the size of Connecticut and Rhode Island combined. A towering mountain, informally named Mount Sharp, rises up nearly three miles above the crater floor. This mammoth feature will provide opportunities for ChemCam to sample geologic layers on the mountainside.
"The amazing thing about the mountain in Gale crater is that it appears from orbit to be entirely sedimentary material," said Nina Lanza, a post-doctoral researcher in LANL’s International, Space, and Response (ISR) division. "This is a collection of sedimentary layers that is nearly three times higher than the Grand Canyon is deep."
Probing this stratified geology with ChemCam could help researchers understand how the Red Planet transformed over time into a drier, less hospitable climate.
Los Alamos also has roles in other aspects of the Mars Science Laboratory. Dave Vaniman of LANL’s Earth and Environmental Sciences Division is deputy leader of another instrument called CheMin, which uses X-ray diffraction to determine the composition of mineral samples collected and dropped into a funnel on the Curiosity rover.
Los Alamos also provided radioisotope fuel processing and encapsulation for the rover's electrical power generator and heat source, called a Multi-Mission Radioisotope Thermoelectric Generator (MMRTG). The generator keeps the rover's battery charged night and day, giving Curiosity the potential of being the longest-operating, farthest-traveling, most-productive Mars surface mission in history.
Weighing nearly a ton, Curiosity is the largest rover ever deployed to another planet. Previously, NASA sent a pair of much smaller rovers, Spirit and Opportunity, to Mars in January 2004. Both rovers gathered a wide range of rock and soil data that have helped provide important information about the wet environments on ancient Mars that may have been favorable to supporting microbial life. The Opportunity rover continues to gather data and send images and information back to Earth—surpassing its planned mission by many years
FROM: LOS ALAMOS NATIONAL LABORATORY
Los Alamos Laser Instrument Arrives on Red Planet’s Surface
LANL ChemCam to be tested soon and will begin probing Mars mysteries
LOS ALAMOS, NEW MEXICO, August 6, 2012—Los Alamos National Laboratory scientists are elated by Sunday’s successful landing of NASA’s Curiosity rover on Mars, and are ready to begin a nearly two-year-long mission that will use a rock-zapping laser device mounted on the mast of the SUV-sized rover to help unravel mysteries of the Red Planet. The ChemCam laser characterization instrument was developed at LANL and the French space institute, IRAP.
"I can’t describe the feeling when we realized that Curiosity had landed safely on the planet," said LANL planetary scientist Roger Wiens, principal investigator of the Mars Science Laboratory mission’s ChemCam team. "My own curiosity about Mars began when I was a boy, and having an instrument that I’ve handled land on the Martian surface fulfills a lifelong dream that started long ago with a backyard telescope. This is an extremely happy, fulfilling moment."
The ChemCam system is one of 10 instruments mounted on the MSL mission’s Curiosity rover—a six-wheeled mobile laboratory that will roam more than 12 miles of the planet’s surface during the course of one Martian year (98 Earth weeks). When ChemCam fires its extremely powerful laser pulse, it briefly focuses the energy of a million light bulbs onto an area the size of a pinhead. The laser blast vaporizes part of its target up to seven meters (23 feet) away.
The resultant flash of glowing plasma is viewed by the system’s 4.3-inch aperture telescope, which records the colors of light within the flash. These spectral colors are then interpreted by a spectrometer, enabling scientists to determine the elemental composition of the vaporized material. ChemCam also has a high-resolution camera that provides close-up images of an analyzed location. It can image a human hair from seven feet away.
The core ChemCam team is comprised of Los Alamos National Laboratory researchers and scientists from IRAP, a partner institution in Toulouse, France. Scientists from around the U.S., France, Canada, and the United Kingdom, along with post-doctoral researchers and students from LANL, round out the entire 45-person team.
Sometime around August 10 (sol 4 in Martian days after landing), the ChemCam team expects to take images of calibration targets mounted on the Rover. These initial tests will help scientists determine the integrity of the ChemCam system and the pointing capability of the rover’s mast, which supports ChemCam’s laser and telescope.
The ChemCam instrument is the first to perform active remote sensing on the surface of the Red Planet. It can deliver three laser pulses each second to a single area, or it can quickly zap multiple areas, providing researchers with great versatility for sampling the surface of the planet. The first few laser pulses remove dust that would otherwise obscure the target surface, enabling scientists to observe the underlying sample. In that sense, the laser is like a long arm that can reach out more than twenty feet and brush off a sample before analysis.
The laser can profile through and study surface coatings on rocks, which, Earth scientists have learned, can often provide important clues to climate and water interaction, and can indicate biological interaction with surface materials. ChemCam is designed to look for lighter elements such as hydrogen, carbon, nitrogen, and oxygen, all of which are crucial for life, as well as to determine abundances of other elements.
After firing its laser, the ChemCam system looks at the entire visible spectrum as well as portions on either side (the infrared and ultraviolet), which gives the instrument the ability to see any element in the periodic table. Researchers expect to take the first analyses of the Martian surface sometime on or after sol 11 or 12 (August 17-18). The system is designed to capture as many as 14,000 observations throughout the mission.
Curiosity is expected to investigate the Gale Crater located close to the equator near the boundary between the southern highlands and the more featureless northern low plains of Mars. The massive crater spans 96 miles in diameter, an area roughly equivalent to the size of Connecticut and Rhode Island combined. A towering mountain, informally named Mount Sharp, rises up nearly three miles above the crater floor. This mammoth feature will provide opportunities for ChemCam to sample geologic layers on the mountainside.
"The amazing thing about the mountain in Gale crater is that it appears from orbit to be entirely sedimentary material," said Nina Lanza, a post-doctoral researcher in LANL’s International, Space, and Response (ISR) division. "This is a collection of sedimentary layers that is nearly three times higher than the Grand Canyon is deep."
Probing this stratified geology with ChemCam could help researchers understand how the Red Planet transformed over time into a drier, less hospitable climate.
Los Alamos also has roles in other aspects of the Mars Science Laboratory. Dave Vaniman of LANL’s Earth and Environmental Sciences Division is deputy leader of another instrument called CheMin, which uses X-ray diffraction to determine the composition of mineral samples collected and dropped into a funnel on the Curiosity rover.
Los Alamos also provided radioisotope fuel processing and encapsulation for the rover's electrical power generator and heat source, called a Multi-Mission Radioisotope Thermoelectric Generator (MMRTG). The generator keeps the rover's battery charged night and day, giving Curiosity the potential of being the longest-operating, farthest-traveling, most-productive Mars surface mission in history.
Weighing nearly a ton, Curiosity is the largest rover ever deployed to another planet. Previously, NASA sent a pair of much smaller rovers, Spirit and Opportunity, to Mars in January 2004. Both rovers gathered a wide range of rock and soil data that have helped provide important information about the wet environments on ancient Mars that may have been favorable to supporting microbial life. The Opportunity rover continues to gather data and send images and information back to Earth—surpassing its planned mission by many years
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