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PRESS RELEASE
06.05.2013
Source: Jet Propulsion Laboratory

NASA's Curiosity Mars Rover Nears Turning Point

Drilled Hole and ChemCam Marks at 'Cumberland'
Drilled Hole and ChemCam Marks at 'Cumberland'
The Chemistry and Camera (ChemCam) instrument on NASA's Mars rover Curiosity was used to check the composition of gray tailings from the hole in rock target "Cumberland" that the rover drilled on May 19, 2013.

PASADENA, Calif. - NASA's Mars Science Laboratory mission is approaching its biggest turning point since landing its rover, Curiosity, inside Mars' Gale Crater last summer.

Curiosity is finishing investigations in an area smaller than a football field where it has been working for six months, and it will soon shift to a distance-driving mode headed for an area about 5 miles (8 kilometers) away, at the base of Mount Sharp.

In May, the mission drilled a second rock target for sample material and delivered portions of that rock powder into laboratory instruments in one week, about one-fourth as much time as needed at the first drilled rock.

"We're hitting full stride," said Mars Science Laboratory Project Manager Jim Erickson of NASA's Jet Propulsion Laboratory, Pasadena, Calif. "We needed a more deliberate pace for all the first-time activities by Curiosity since landing, but we won't have many more of those."

No additional rock drilling or soil scooping is planned in the "Glenelg" area that Curiosity entered last fall as the mission's first destination after landing. To reach Glenelg, the rover drove east about a third of a mile (500 meters) from the landing site. To reach the next destination, Mount Sharp, Curiosity will drive toward the southwest for many months.

"We don't know when we'll get to Mount Sharp," Erickson said. "This truly is a mission of exploration, so just because our end goal is Mount Sharp doesn't mean we're not going to investigate interesting features along the way."

Images of Mount Sharp taken from orbit and images Curiosity has taken from a distance reveal many layers where scientists anticipate finding evidence about how the ancient Martian environment changed and evolved.

While completing major first-time activities since landing, the mission has also already accomplished its main science objective. Analysis of rock powder from the first drilled rock target, "John Klein," provided evidence that an ancient environment in Gale Crater had favorable conditions for microbial life: the essential elemental ingredients, energy and ponded water that was neither too acidic nor too briny.

The rover team chose a similar rock, "Cumberland," as the second drilling target to provide a check for the findings at John Klein. Scientists are analyzing laboratory-instrument results from portions of the Cumberland sample. One new capability being used is to drive away while still holding rock powder in Curiosity's sample-handling device to supply additional material to instruments later if desired by the science team.

For the drill campaign at Cumberland, steps that each took a day or more at John Klein could be combined into a single day's sequence of commands. "We used the experience and lessons from our first drilling campaign, as well as new cached sample capabilities, to do the second drill campaign far more efficiently," said sampling activity lead Joe Melko of JPL. "In addition, we increased use of the rover's autonomous self-protection. This allowed more activities to be strung together before the ground team had to check in on the rover."

The science team has chosen three targets for brief observations before Curiosity leaves the Glenelg area: the boundary between bedrock areas of mudstone and sandstone, a layered outcrop called "Shaler" and a pitted outcrop called "Point Lake."

JPL's Joy Crisp, deputy project scientist for Curiosity, said "Shaler might be a river deposit. Point Lake might be volcanic or sedimentary. A closer look at them could give us better understanding of how the rocks we sampled with the drill fit into the history of how the environment changed."

For more about the mission, visit: http://www.nasa.gov/msl .
You can follow the mission on Facebook and Twitter at: http://www.facebook.com/marscuriosity and http://www.twitter.com/marscuriosity .

Watch related video.


All Related Images
  • This image from the Mast Camera (Mastcam) on NASA's Mars rover Curiosity shows inclined layering known as cross-bedding in an outcrop called "Shaler" on a scale of a few tenths of meters, or decimeters (1 decimeter is nearly 4 inches).
    'Shaler' Unit's Evidence of Stream Flow
  • The "Shaler" outcrop is dramatically layered, as seen in this mosaic of telephoto images from the right Mast Camera (Mastcam) on NASA's Mars rover Curiosity.
    Wide View of 'Shaler' Outcrop, Sol 120
  • From 'Glenelg' to Mount Sharp
    From 'Glenelg' to Mount Sharp
  • This is a sequence of images from the Front Hazard-Avoidance Camera on NASA's Mars rover Curiosity that shows the rover drilling into rock target "Cumberland."
    Curiosity Mars Rover Drilling Into Its Second Rock
  • 'Point Lake' Outcrop in Gale Crater, Raw Color
    'Point Lake' Outcrop in Gale Crater, Raw Color
  • Concretions at 'Cumberland'
    Concretions at 'Cumberland' (Annotated)
  • Concretions at 'Cumberland'
    Concretions at 'Cumberland'
  • Checking Contact Points for Curiosity's Drill
    Checking Contact Points for Curiosity's Drill (Annotated)
  • Checking Contact Points for Curiosity's Drill
    Checking Contact Points for Curiosity's Drill
  • 'Point Lake' Outcrop in Gale Crater
    'Point Lake' Outcrop in Gale Crater
  • Drilled Hole and ChemCam Marks at 'Cumberland'
    Drilled Hole and ChemCam Marks at 'Cumberland'
  • Position of Curiosity for Drilling at 'Cumberland'
    Position of Curiosity for Drilling at 'Cumberland' (Annotated)
  • Position of Curiosity for Drilling at 'Cumberland'
    Position of Curiosity for Drilling at 'Cumberland'

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Guy Webster 818-354-6278
Jet Propulsion Laboratory, Pasadena, Calif.
guy.webster@jpl.nasa.gov


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