A model of the Mars rover "Curiosity "is tested at the Jet Propulsion… (Gary Friedman / Los Angeles…)
One of the most sophisticated space vehicles ever made inches along the rocky landscape, aluminum wheels grinding like a spoon in a garbage disposal.
Here in the Mars Yard at the Jet Propulsion Laboratory, what passes for the Red Planet looks like a vacant lot in Hesperia. The vehicle being tested, a replica of the latest Mars rover that will soon be crawling around up there, looks like a giant mechanical insect — six wheeled legs, an articulating arm and a pair of blue camera lenses like eyes peering from a boxy head.
This month, NASA's most ambitious Mars rover mission to date is scheduled to lift off from Cape Canaveral, Fla., aboard an Atlas V rocket. It's a $2.5-billion gamble scientists hope will give unparalleled insights into how Mars evolved and whether it ever could have supported life.
The Mars Science Laboratory — nicknamed Curiosity — was developed at JPL in La Cañada Flintridge and will be the fourth rover to traverse the planet's harsh terrain. But unlike the earlier Mars rovers — Sojourner, Spirit and the still-cruising Opportunity — Curiosity will do more than look for evidence of water.
Curiosity is a robot astrobiologist. During a mission expected to last at least two years, the rover will use a battery of scientific instruments to analyze Mars' geology and atmosphere, looking for the elements and chemical compounds that are the building blocks of life.
Scientists hope the information Curiosity gathers will exponentially increase their understanding of Mars and bring us closer to answering the most profound and tantalizing of questions: Could life exist beyond Earth?
"Humans are hard-wired to want to know the answer to that," said Bill Nye, executive director of the Planetary Society, the Pasadena-based nonprofit that advocates for space exploration. "If we found life on Mars, it would change everybody's view of our place in space."
Curiosity will take 8.5 months to travel the 354 million miles to Mars — and two years to cover about 14 miles of its surface.
The rover is expected to land Aug. 5 near the Martian equator inside Gale crater, a chasm about the combined size of Connecticut and Rhode Island with a 3-mile-high mountain of layered sedimentary rock at its bottom.
Scientists believe the crater, thought to date back billions of years to when Mars was warm and wet, will reveal the planet's evolutionary story the way the Grand Canyon's strata expose the history of Earth.
"It's going to be like reading a novel — and it's a long one," said John Grotzinger, the project's chief scientist. "It's going to be a wild journey looking into the guts of the history of Mars."
If Curiosity were a car, it would be advertised as fully loaded: six aluminum wheels that can be steered independently. A mounted laser to vaporize rock. Seventeen cameras to take high-definition images, scientific measurements and navigate the rover. A robotic arm to drill into rock and scoop up samples. Instruments to detect in those samples organic compounds and elements associated with life on Earth.
And under the hood: a nuclear-powered engine that will give Curiosity a top crawling speed of 2 inches per second.
All that hardware gives the rover a curb weight of a ton. That's five times heavier than its predecessor, which bounced along the Martian surface nestled inside huge protective air bags before coming to rest, like a beach ball tossed from a low-flying airplane.
"The air bags needed to land Curiosity would have been two or three times the weight of the rover itself," said Adam Steltzner, a JPL engineer in charge of ensuring the rover lands in one piece. "There's no landing rocket that could have handled that weight."
So Steltzner's team has engineered an innovative, multi-staged system that, unlike the beach ball approach, will use sensors and advanced computer software to guide Curiosity's descent to a relatively pinpoint landing.
As planned, the craft carrying the rover will hit Mars' atmosphere at 13,000 mph. Thruster rockets will slow and steer the craft, positioning it for landing. At about 1,000 mph, a parachute will deploy and slam on the brakes. Finally, a "sky crane" will emerge from the craft's descent stage and gently lower a tethered Curiosity to the ground.
All this in just six minutes.
"It looks kind of crazy. And it's definitely novel," Steltzner said. "But we believe it to be a very simple process."
A lot is at stake.
The Curiosity rover is one of most complex projects in NASA's history. It's also $900 million over budget and two years late.
An audit released earlier this year by NASA's inspector general criticized managers for repeatedly underestimating the cost of working around the project's numerous technological hurdles — a common complaint of the agency through the years.
All this comes at a time of budget cutting at NASA and a lack of consensus among scientists and politicians as to where the U.S. space program ought to devote dwindling dollars.