“It is good to renew one’s wonder, said the philosopher. “Space travel has again made children of us all.”—Ray Bradbury (from The Martian Chronicles)
“The Phoenix spacecraft successfully landed in the north arctic plains of Mars today,” Carolyn Porco, Cassini Imaging Team Leader, announced to my friend Danny Bloom. “This is the first landing in 32 years — since the Viking spacecraft made landfall on Mars in 1976 — that we have soft-landed a craft on Mars using retrorockets.”
“The Phoenix spacecraft successfully landed in the north arctic plains of Mars today,” Carolyn Porco, Cassini Imaging Team Leader, announced to my friend Danny Bloom. “This is the first landing in 32 years — since the Viking spacecraft made landfall on Mars in 1976 — that we have soft-landed a craft on Mars using retrorockets.”
The lander successfully parachuted and touched down on the surface of Mars Sunday, despite some fears about the spacecraft’s ability to penetrate the atmosphere and remain upright after landing. Had the Phoenix tipped over, it would not have been able to dig into Martian soil, and it would have been impossible for the craft to complete its mission, reported K.C. Jones of InformationWeek .
“I’m floored. I’m absolutely floored,” said Phoenix Project Manager Barry Goldstein of NASA’s Jet Propulsion Laboratory (JPL), in Pasadena, Calif. Mars Society executive director Chris Carberry said that one of the greatest challenges in modern engineering is to land a craft safely on another planet. “The data collected from this mission could have a tremendous impact on planning for future human missions,” he said.
“From the pictures returned, the spacecraft is in a completely uprig
ht position, the solar arrays are perfectly deployed, and the surroundings show no large rocks or boulders but a rather hummocky surface, perhaps created by the action of sub-surface ice,” said Porko. “This spacecraft is not meant to rove but to dig and analyze. So, now begins three months of gradual digging with the spacecraft’s robotic arm and scoop until eventually it reaches the ice layer beneath the surface. The goal [is] to determine if the icy sub-surface environment is rich in organics and suitable for living organisms, and perhaps if there are any organisms living there today. It will be three months of great anticipation.”
ht position, the solar arrays are perfectly deployed, and the surroundings show no large rocks or boulders but a rather hummocky surface, perhaps created by the action of sub-surface ice,” said Porko. “This spacecraft is not meant to rove but to dig and analyze. So, now begins three months of gradual digging with the spacecraft’s robotic arm and scoop until eventually it reaches the ice layer beneath the surface. The goal [is] to determine if the icy sub-surface environment is rich in organics and suitable for living organisms, and perhaps if there are any organisms living there today. It will be three months of great anticipation.”
“Our long-term goals are to determine whether life ever arose on Mars, to examine climate, characterise geology and prepare for human exploration,” said Peter Smith, Phoenix Project Lead Investigator. “Mars is a cold desert planet with no liquid water on its surface. However, discoveries made by the Mars Odyssey Orbiter in 2002 showed large amounts of subsurface water ice. The Phoenix Lander targets this region.”
“Phoenix will probe the history of liquid water that may have existed in the arctic as recently as 10
0,000 years ago,” added Smith. “Evidence from other missions suggest that water once flowed in canyons. It is important because all known life forms require it to survive. Chemical experiments will assess the soil’s composition of life-giving elements such as carbon, nitrogen, phosphorus, and hydrogen. Certain bacterial spores lie dormant in cold, dry and airless conditions for millions of years and become activated in favourable conditions. Such dormant microbial colonies may exist in the Martian arctic.”
0,000 years ago,” added Smith. “Evidence from other missions suggest that water once flowed in canyons. It is important because all known life forms require it to survive. Chemical experiments will assess the soil’s composition of life-giving elements such as carbon, nitrogen, phosphorus, and hydrogen. Certain bacterial spores lie dormant in cold, dry and airless conditions for millions of years and become activated in favourable conditions. Such dormant microbial colonies may exist in the Martian arctic.”
“Images sent back from the Red Planet by NASA’s Phoenix Mars Lander after its picture-perfect Sunday touchdown provide the first close-up views of a barren landscape honeycombed with cracks that may represent the effects of seasonal freezing and thawing of subsurface ice,” reported J.R. Minkel of Scientific American Online.
The robotic arm camera on board the Phoenix Mars lander features the first motor-adjustable focusing system to be deployed on an inter-planetary spacecraft, Nasa revealed (Chris Cheesman of Amateur Photographer). Scientists are now analyzing photographs captured by the spacecraft, the first taken since it touched down on 25 May. Phoenix’s robotic arm camera aims to provide close-up color images of Martian soil and ice samples that could
establish whether the planet could support life. The camera is positioned just above the ‘scoop’ that aims to collect samples dug by the robotic arm, says Cheesman. “The camera has a double Gauss lens system, a design commonly used in 35mm cameras,” explains the space agency. “Images are recorded by a charge-coupled device (CCD) similar to those in consumer digital cameras. The instrument includes sets of red, green and blue light-emitting diodes (LEDs) for illuminating the target area.” Nasa claims that the camera can focus down to 11mm and record images at a resolution of ’23 microns per pixel’ at the closest focusing distance – allowing the camera to show details ‘much finer than the width of a human hair’. The camera is similar to one used on the failed Mars Polar Lander spacecraft but with a revamped illumination system.
establish whether the planet could support life. The camera is positioned just above the ‘scoop’ that aims to collect samples dug by the robotic arm, says Cheesman. “The camera has a double Gauss lens system, a design commonly used in 35mm cameras,” explains the space agency. “Images are recorded by a charge-coupled device (CCD) similar to those in consumer digital cameras. The instrument includes sets of red, green and blue light-emitting diodes (LEDs) for illuminating the target area.” Nasa claims that the camera can focus down to 11mm and record images at a resolution of ’23 microns per pixel’ at the closest focusing distance – allowing the camera to show details ‘much finer than the width of a human hair’. The camera is similar to one used on the failed Mars Polar Lander spacecraft but with a revamped illumination system.
The Phoenix also carries a Canadian weather station. The $37 million station is no larger than a 
shoebox and wrapped in a thermal blanket bearing a tiny Maple Leaf flag. The station will help in the search for life-giving water. It’s the first Canadian science instrument to land on the surface of an alien world, said Alicia Chang, of the Associated Press. A Canadian scientific team hopes to spend 90 days studying data sent back from Mars, including daily measurements of temperature, atmospheric pressure, cloud height, humidity and wind speeds. A specially developed laser called a lidar will be used to track clouds around the landing area. Steve MacLean, chief astronaut for the Canadian Space Agency, told the Canadian Press that Canada got involved because of its expertise operating in frigid northern environments.
shoebox and wrapped in a thermal blanket bearing a tiny Maple Leaf flag. The station will help in the search for life-giving water. It’s the first Canadian science instrument to land on the surface of an alien world, said Alicia Chang, of the Associated Press. A Canadian scientific team hopes to spend 90 days studying data sent back from Mars, including daily measurements of temperature, atmospheric pressure, cloud height, humidity and wind speeds. A specially developed laser called a lidar will be used to track clouds around the landing area. Steve MacLean, chief astronaut for the Canadian Space Agency, told the Canadian Press that Canada got involved because of its expertise operating in frigid northern environments.Yup, I can vouch for that…
