NASA's new Mars rover Curiosity called scientific dream machine

The new NASA Mars rover Curiosity blows away its predecessors in size and skill, its makers say.

Mission to check planet's 'habitability,' pave way for astronauts

The APXS (alpha ray X-ray spectrometer) will be carried aboard NASA's Mars Science Laboratory rover Curiosity, shown here undergoing tests at NASA's Jet Propulsion Laboratory in Pasadena, Calif., in mid-September. (NASA/JPL-Caltech)

As big as a car and as well-equipped as a laboratory, the new NASA Mars rover scheduled to launch Nov. 26 blows away its predecessors in size and skill, its makers say.

Nicknamed Curiosity and scheduled for launch from Cape Canaveral, Fla., the rover has a 2.1-metre arm tipped with a jackhammer and a laser to break through the Martian red rock. What really makes it stand out: It can analyze rocks and soil with unprecedented accuracy.

"This is a Mars scientist's dream machine," said NASA Jet Propulsion Laboratory's Ashwin Vasavada, the deputy project scientist.

Once on the red planet, Curiosity will be on the lookout for organic, carbon-containing compounds. While the rover can't actually detect the presence of living organisms, scientists hope to learn from the $2.5 billion US, nuclear-powered mission whether Mars has — or ever had — what it takes to nurture microbial life. 

Curiosity will be "the largest and most complex piece of equipment ever placed on the surface of another planet," said Doug McCuistion, director of NASA's Mars exploration program.

Three metres long, 2.7 metres wide and 2.1 metres tall at its mast, Curiosity is about twice the size of previous rovers Spirit and Opportunity. It weighs 0.9 tonnes and is loaded with 10 science instruments. Its formal name: Mars Science Laboratory, or MSL.

There will be more anxiety than usual over the launch. Curiosity holds 4.6 kilograms of plutonium, more than enough to power the rover on the Martian surface for two years. A nuclear generator won out over solar energy because it allows for a bigger workload and more flexibility. The plutonium is encased in several protective layers in case of a launch accident.

While the rover can't actually detect the presence of living organisms, scientists hope to learn whether Mars could have supported microbial life. (NASA)
After traveling from Earth in a spacecraft, Curiosity will be lowered to Mars' surface via a jet pack and a tether system similar to the sky cranes used by helicopters to insert heavy equipment in inaccessible spots on Earth. No bouncing air bags like those used for the Mars Pathfinder lander and rover in 1997 and for Spirit and Opportunity in 2004 — Curiosity is too heavy for that.

It is the kind of precision landing that officials said will benefit future human explorers on Mars.

The rover is scheduled to arrive at the mineral-rich Gale Crater next August, 8 and a half months after embarking on the 569.7-million-kilometre voyage aboard an Atlas V rocket.

Treacherous trip

It's a treacherous journey to Mars, and the road is littered with failures. In all, more than three dozen missions have aimed over the decades at the most Earth-like planet known, and fewer than half have succeeded. Of this flotilla, only one lander is still working on the dry, barren, cold surface — Opportunity — and only three craft still are observing the planet from orbit.

In fact, Russia's latest Mars probe remains stuck in orbit around Earth two weeks after its botched launch. NASA has had better luck at Mars, although it has lost a few spacecraft there.

"Mars is difficult, and so many things have to go right for a mission to work," said Michael Meyer, lead scientist for NASA's Mars exploration program.

Curiosity is the capstone of what NASA calls the year of the solar system. A spacecraft is en route to Jupiter after lifting off last August from Cape Canaveral, and twin lunar probes launched in September will arrive at the moon New Year's weekend.


Once safely down on Mars, the rover will survey the landscape with high-definition and laser cameras mounted like eyes atop its mast. The laser will aim at soil and rocks as far as 7 metres away to gauge their chemical composition.

The rover also has a weather station for updates on Martian temperature, humidity and wind, as well as a radiation detector that will be especially useful for planning human expeditions.

In this artist's rendering, a sky crane lowers the Mars Science Laboratory Curiosity rover onto the surface of Mars. (NASA/JPL-Caltech)
Despite all its fancy upgrades, Curiosity will go no faster than the 0.16-kilometres-per-hour logged by past Martian rovers. But it is expected to venture more than 20 kilometres during its two-year mission. If it's still working after that, it will keep on trucking, possibly all the way up the crater's 4.8-kilometre peak.

This mountain is composed of geologic layers similar to what one might find in the Grand Canyon, said project scientist John Grotzinger, a geologist at the California Institute of Technology.

"Our rover is going to be like John Wesley Powell going down the Grand Canyon," Grotzinger said, referring to the 19th-century explorer who led an expedition down the Colorado River.

The next logical step in Mars exploration, said Cornell University's Steve Squyres, who led the science team for Spirit and Opportunity, would be a robotic mission to deliver Mars samples to Earth for analysis. NASA hopes to pull that off later this decade, but the project is on Congress' chopping block.

Squyres warned that without such missions, U.S. leadership in science won't just be challenged — "it's going to go away."