Nasa's Curiosity rover prepares to zap Martian rocks
This 7cm rock is about to become the first object on Mars to be zapped by Curiosity's laser instrument
Nasa's Curiosity rover is getting ready to zap its first Martian rock.
A small stone lying just to the side of the vehicle at its
landing site on the floor of Gale Crater has been selected as a test
target for the ChemCam laser.The brief but powerful burst of light from this instrument will vaporise the surface of the rock, revealing details of its basic chemistry.
Dubbed N165, the object is not expected to have any science value, but should show ChemCam is ready for serious work.
"I'd probably guess this is a typical Mars basalt - basaltic rocks making up a large fraction of all the igneous rocks on Mars," Roger Wiens, the instrument's principal investigator, told BBC News.
"A basalt, which is also common under the ocean on Earth, typically has 48% silicon dioxide and percent amounts of iron, calcium and magnesium, and sodium and potassium oxides as well. We're not expecting any surprises," said the Los Alamos National Laboratory researcher.
Curiosity touched down in its equatorial crater two weeks ago.
Hot spot Its mission is to investigate the rocks at its landing site for evidence that past environments could have supported life.
Curiosity - Mars Science Laboratory
- Mission goal is to determine whether Mars has ever had the conditions to support life
- Project costed at $2.5bn; will see initial surface operations lasting two Earth years
- Onboard plutonium generators will deliver heat and electricity for at least 14 years
- 75kg science payload more than 10 times as massive as those of earlier US Mars rovers
- Equipped with tools to brush and drill into rocks, to scoop up, sort and sieve samples
- Variety of analytical techniques to discern chemistry in rocks, soil and atmosphere
- Will try to make first definitive identification of organic (carbon rich) compounds
The rover carries a suite of
instruments for the purpose, but its Chemistry and Camera (ChemCam)
experiment has probably garnered most attention because nothing like it
has ever been flown to Mars before.
ChemCam sits high up on the rover's mast from where it directs a laser beam on to rocks up to 7m (23ft) away.The spot hit by the infrared laser gets more than a million watts of power focused on it for five one-billionths of a second.
This produces a spark that the instrument observes with a telescope. The colours tell scientists which atomic elements are present in the rock.
ChemCam is going to be a key part of the process of selecting science targets during Curiosity's two-year mission.
If the laser shows up an interesting rock, the vehicle will move closer and deploy its other instruments for a more detailed investigation.
Fire marks Assuming the test with the 7cm-wide N165 object goes well, ChemCam will move on to its first science target.
This will be rock exposed on the ground next to the rover by
the rocket-powered crane used to lower the vehicle to the crater floor.
Goulburn Scour: The descent crane blew away pebbles and grit to expose underlying rock
The crane made four scour marks in the ground - two either side of Curiosity. These have been dubbed Burnside, Goulburn, Hepburn and Sleepy Dragon.
The names, all related to fire, are taken from ancient rock formations in Canadian North America.
Goulburn Scour will be zapped by ChemCam.
"There's bedrock exposed beneath the soil with interesting patterns of colour," said John Grotzinger, Curiosity's project scientist.
"There're lighter parts; there're darker parts, and the team is busy deliberating over how this rock unit may have formed and what it's composed of. We'll aim the ChemCam [at Goulburn Scour], as well as taking even higher resolution images."
The science team has decided to send the rover to the intersection of three geological terrains
Curiosity has not moved since landing on 6 August (GMT). That is about to change.The rover is going to roll forward briefly to test its locomotion system in the next few days. A reverse manoeuvre is planned, also.
Researchers want eventually to drive several kilometres to the base of the big mountain at the centre of Gale Crater to study sediments that look from satellite pictures to have been laid down in the presence of abundant water.
This journey to the foothills of Mount Sharp is going to have to wait a few months, however, because the science team intends first to go in the opposite direction.
Several hundred metres to the east of Curiosity's present position is an intersection of three geological terrains.
Again, this location has been given a name - Glenelg. And, again, it is taken from the geology of North America.
The intersection is intriguing and a good place to compare and contrast with the bedrock exposed in Goulburn Scour.
In addition, it may provide access to older, harder rocks. These could make for a first opportunity for Curiosity to use its drill.
"Even though it is in the opposite direction from the path to Mount Sharp, it's the one place we can go to to capture a lot of the information that's persevered in our landing [location]," Prof Grotzinger told Azadamrevolution.
- (A) Curiosity will trundle around its landing site looking for interesting rock features to study. Its top speed is about 4cm/s
- (B) This mission has 17 cameras. They will identify particular targets, and a laser will zap those rocks to probe their chemistry
- (C) If the signal is significant, Curiosity will swing over instruments on its arm for close-up investigation. These include a microscope
- (D) Samples drilled from rock, or scooped from the soil, can be delivered to two hi-tech analysis labs inside the rover body
- (E) The results are sent to Earth through antennas on the rover deck. Return commands tell the rover where it should drive next
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