Curious About Curiosity’s Chemistry Mission?

The Mars Science Laboratory will be seeking clues to the planetary puzzle about life on Mars, the Curiosity rover is one of the best-outfitted chemistry missions ever. Scientists say Curiosity is the next best thing to launching a team of trained chemists to Mars’ surface.

“The Mars Science Laboratory mission has the goal of understanding whether its landing site on Mars was ever a habitable environment, a place that could have supported microbial life,” says MSL Deputy Project Scientist, Ashwin Vasavada, who provides a look “under the hood” in this informative video from the American Chemical Society.

“Curiosity is really a geochemical experiment, and a whole laboratory of chemical equipment is on the rover,” says Vasavada. “It will drill into rocks, and analyze material from those rocks with sophisticated instruments.”

Curiosity will drive around the landing site at Gale Crater and sample the soil, layer by layer, to piece together the history of Mars, trying to determine if and when the planet went from a wetter, warmer world to its current cold and dry conditions.

The payload includes mast-mounted instruments to survey the surroundings and assess potential sampling targets from a distance, and there are also instruments on Curiosity’s robotic arm for close-up inspections. Laboratory instruments inside the rover will analyze samples from rocks, soils and the atmosphere.

The two instruments on the mast are a high-definition imaging system, and a laser-equipped, spectrum-reading camera called ChemCam that can hit a rock with a special laser beam, and using Laser Induced Breakdown Spectroscopy, can observe the light emitted from the laser’s spark and analyze it with the spectrometer to understand the chemical composition of the soil and rock on Mars.

The tools on the turret at the end of Curiosity’s 2.1-meter-long (7-foot-long) robotic arm include a radiation-emitting instrument that reads X-ray clues to targets’ composition and a magnifying-lens camera. The arm can deliver soil and powdered-rock samples to an instrument that uses X-ray analysis to identify minerals in the sample and to an instrument that uses three laboratory methods for assessing carbon compounds and other chemicals important to life and indicative of past and present processes.

The three methods are an evolved gas experiment, which uses a mass spectrometer to look for potential long chain organic molecules on Mars; CheMin, an X-ray diffraction experiment to determine mineralogy; and an Alpha Particle X-Ray Spectrometer (APXS) on Curiosity’s robotic arm, like its predecessors on the arms of all previous Mars rovers, will identify chemical elements in rocks and soils.

In total Curiosity has 10 different instruments on board the roving laboratory, and test results from these instruments will pave the way for future Mars missions, and may provide insight in the search for life on other planets.

Image caption: Artist depiction of the Curiosity rover on Mars. Credit: NASA

Sources: NASA, ACS

What Will Curiosity’s “View” Be as it Approaches the Red Planet?

Curiosity made a risky landing that was partly made possible from learning from mistakes, according to a NASA official. Credit: NASA

Imagine if you were tucked away inside the Mars Science Laboratory backshell, just like the Curiosity rover. What would you see as you approached Mars? Bill Dunford from Riding With Robots on the High Frontier wanted to know the same thing. “I was wondering what Mars would look like if you could physically ride along,” he wrote. “If you were somehow onboard the spacecraft that’s carrying the rover, and you had a window to look through, what would you be able to see?”

To find out, he took advantage of NASA’s Eyes on the Solar System website. This amazing tool creates realistic simulated views based on real data, and allows you to travel to any planet, moon or spacecraft across time and space, in 3D and in real time. It is absolutely awesome and very fun to play with! Bill created the video above by using Eyes on the Solar System, which provides a great look at the view approaching Mars.

Then, Bill also used Eyes on the Solar System to follow Curiosity down to the surface and view the landing, which, if all goes well on 10:31 p.m. PDT on August 5th (05:31 UTC on Aug. 6), should look something like this:

Of course, no one will be there on Mars to see it happen, and we won’t know for at least 14 minutes after the fact if it happened successfully. So consider yourself lucky to have this sneak peak!

See more screenshots and information at Riding With Robots, and check out Bill’s one-page “Cheat Sheet” which provides a quick guide to the mission and the landing, with links to all sorts of information.

Join Universe Today’s Live Webcast of the Curiosity Rover Landing

The NASA team threw in every bit of data they could to model the Mars Curiosity landing. Credit: NASA

Want to be part of the Mars Science Laboratory landing event and join thousands of others in watching it live? Universe Today is teaming up with Google, the SETI Institute and CosmoQuest to provide unprecedented, live coverage of the historic landing of the Curiosity rover on Mars. Starting at 8 pm PDT on August 5th (03:00 UTC August 6th) a live, 4-hour webcast will highlight the landing of the car-sized robotic roving laboratory. During the webcast, via a Google+ Hangout on Air, scientists, engineers and other experts will provide unique insight into the rover and the landing, and viewers will have the chance to interact and ask questions.

Hosted by Universe Today’s Fraser Cain, along with Dr. Pamela Gay and Dr. Phil Plait, the webcast will feature interviews with special guests, a live video feed from NASA of the landing, and live coverage from the Jet Propulsion Laboratory (JPL) and the Planetary Society’s PlanetFest by reporters Scott Lewis and Amy Shira Teitel, who will be on location to interview members of the MSL team, as well as and other scientists and NASA officials that will be on hand.

The landing itself is scheduled for 10:31 p.m. PDT Aug. 5 (05:31 UTC Aug. 6). Curiosity’s landing will mark the start of a two-year mission to investigate whether one of the most intriguing places on Mars ever has offered an environment favorable for microbial life.

As you know, Universe Today, in collaboration with CosmoQuest hosts weekly virtual star parties and science conversations via Google+ Hangouts on Air, and for the Transit of Venus, hosted a special Hangout event that was watched by nearly 7,000 viewers.

Those interested in watching Universe Today’s MSL landing event can find more information and also sign up to “attend” the Hangout on Air here.

The feed will also be available on Universe Today’s YouTube live feed.

You can also follow the action via Twitter from Universe Today (@universetoday) and CosmoQuest (@CosmoQuestX ) by using the hashtag #marshangout

We also have the event listed on Facebook.

Curiosity’s Grand Entrance with Star Trek’s William Shatner and Wil Wheaton – Video Duet

Video Caption: Star Trek’s Captain Kirk, actor William Shatner, guides viewers through the video titled, “Grand Entrance,” showing NASA’s Curiosity Mars Science Lab mission from atmospheroic entry through descent, and after landing on the Red Planet on August 6 2012.

As NASA engineers and scientists make final preparations for the Red Planet landing of NASA’s most difficult planetary science mission to date – the Curiosity Mars Science Lab – inside Gale Crater on the night of August 5/6, Star Trek actors William Shatner and Wil Wheaton lend their voices to a pair of new mission videos titled “Grand Entrance”

The video duet describes the thrilling story of how Curiosity will touch down on Mars and guides viewers through the nail biting “7 Minutes of Terror” – from entry into the Martian atmosphere at over 13,000 MPH and then how the rover must slow down through descent, set down for a soft and safe landing and ultimately how Curiosity will search for signs of life. Continue reading “Curiosity’s Grand Entrance with Star Trek’s William Shatner and Wil Wheaton – Video Duet”

Curiosity Completes Crucial Course Correction – 1 Week from Mars !

Image Caption: Course correcting thruster firings on July 29 successfully placed Curiosity on target to touchdown beside Mount Sharp inside Gale Crater on Mars on Aug 6 in search of signs of a habitable environment. Credit: NASA

Now just 1 week out from landing beside a 3 mile high (5 km) layered Martian mountain in search of life’s ingredients, aiming thrusters aboard the cruise stage of NASA’s car sized Curiosity Mars Science Lab successfully fired to set the rover precisely on course for a touchdown on Mars at about 1:31 a.m. EDT (531 GMT) early on Aug. 6 (10:31 p.m. PDT on Aug. 5).

Two precise and brief thruster bursts lasting about 7 seconds were successfully carried out just hours ago earlier today at 1 a.m. on July 29, EDT (10 p.m. PDT on July 28). The effect was to change the spacecraft’s velocity by about 1/40 MPH or 1 cm/sec as it smashes into Mars at about 13,200 mph (5,900 meters per second).

This was the fourth and possibly last of 6 interplanetary Trajectory Correction Manuevers (TCM’s) planned by mission engineers to steer Curiosity since departing Earth for the Red Planet.

If necessary, 2 additional TCM’s could be implemented in the final 48 hours next Saturday and Sunday before Curiosity begins plunging into the Martian atmosphere late Sunday night on a do or die mission to land inside the 100 mile wide Gale Crater with a huge mountain in the middle. All 6 TCM maneuvers were preplanned long before the Nov 26, 2011 liftoff from Cape Canaveral, Florida.

Without this course correction firing, MSL would have hit a point at the top of the Martian atmosphere about 13 miles (21 kilometers) east of the target entry point. During the preprogrammed Entry, Descent and Landing (EDL) sequence the vehicle can steer itself in the upper atmosphere to correct for an error amounting to a few miles.

On landing day, MSL can steer enough during its flight through the upper atmosphere to correct for missing the target entry aim point by a few miles and still land on the intended patch of Mars real estate. The mission’s engineers and managers rated the projected 13-mile miss big enough to warrant a correction maneuver.

“The purpose of this maneuver is to move the point at which Curiosity enters the atmosphere by about 13 miles,” said Tomas Martin-Mur of NASA’s Jet Propulsion Laboratory, Pasadena, Calif., chief of the mission’s navigation team. “The first look at telemetry and tracking data afterwards indicates the maneuver succeeded as planned.”


Image Cation: Curiosity Mars Science Laboratory Rover – inside the Cleanroom at KSC, with robotic arm extended prior to encapsulation and Nov. 26, 2011 liftoff. Credit: Ken Kremer/kenkremer.com

As of today (July 30), Curiosity has traveled about 97% of the overall journey to Mars or about 343 million miles (555 million kilometers) of its 352-million-mile (567-million-kilometer) total flight distance.

“I will not be surprised if this was our last trajectory correction maneuver,” Martin Mur said of the TCM-4 firing. “We will be monitoring the trajectory using the antennas of the Deep Space Network to be sure Curiosity is staying on the right path for a successful entry, descent and landing.”

Curiosity will use an unprecedented rocket powered descent stage and a helicopter like sky crane to set down astride the sedimentary layers of Mount Sharp.

She will then conduct a minimum 2 year prime mission with the most sophisticated science instrument package ever dispatched to Mars to determine if a habitable zone ever existed on this region of Mars.

Curiosity will search for the ingredients of life in the form of organic molecules – the carbon based molecules which are the building blocks of life as we know it. The one-ton behemoth is packed to the gills with 10 state of the art science instruments including a 7 foot long robotic arm, scoop, drill and laser rock zapper.

As Curiosity dives down to Mars surface on Aug. 6, 3 spacecraft from NASA and ESA are now positioned in orbit around the Red Planet and are ready to relay and record signals from the “7 Minutes of Terror” – Read the details in my article – here

Watch NASA TV online for live coverage of the Curiosity landing on Aug 5/6:
mars.jpl.nasa.gov or www.nasa.gov

Ken Kremer

T Minus 9 Days – Mars Orbiters Now in Place to Relay Critical Curiosity Landing Signals

Image Caption: NASA’s Mars Odyssey will relay near real time signals of this artist’s concept depicting the moment that NASA’s Curiosity rover touches down onto the Martian surface. NASA’s Mars Reconnaissance Orbiter (MRO) and ESA’s Mars Express (MEX) orbiter will also record signals from Curiosity for later playback, not in real time. Credit: NASA

It’s now just T minus 9 Days to the most difficult and complex Planetary science mission NASA has ever attempted ! The potential payoff is huge – Curiosity will search for signs of Martian life

The key NASA orbiter at Mars required to transmit radio signals of a near real-time confirmation of the August 5/6 Sunday night landing of NASA’s car sized Curiosity Mars Science Lab (MSL) rover is now successfully in place, and just in the nick of time, following a successful thruster firing on July 24.

Odyssey will transmit the key signals from Curiosity as she plunges into the Martian atmosphere at over 13,000 MPH (21,000 KPH) to begin the harrowing “7 Minutes of Terror” known as “Entry, Descent and Landing” or EDL – all of which is preprogrammed !

Engines aboard NASA’s long lived Mars Odyssey spacecraft fired for about 6 seconds to adjust the orbiters location about 6 minutes ahead in its orbit. This will allow Odyssey to provide a prompt confirmation of Curiosity’s landing inside Gale crater at about 1:31 a.m. EDT (531 GMT) early on Aug. 6 (10:31 p.m. PDT on Aug. 5) – as NASA had originally planned.

Without the orbital nudge, Odyssey would have arrived over the landing site about 2 minutes after Curiosity landed and the signals from Curiosity would have been delayed.

A monkey wrench was recently thrown into NASA relay signal plans when Odyssey unexpectedly went into safe mode on July 11 and engineers weren’t certain how long recovery operations would take.

“Information we are receiving indicates the maneuver has completed as planned,” said Mars Odyssey Project Manager Gaylon McSmith of NASA’s Jet Propulsion Laboratory, Pasadena, Calif. “Odyssey has been working at Mars longer than any other spacecraft, so it is appropriate that it has a special role in supporting the newest arrival.”

Odyssey has been in orbit at Mars since 2001 conducting orbital science investigations.

Read my review article on Odyssey’s science discoveries – here

Odyssey serves as the primary communications relay for NASA’s other recent surface explorers – Opportunity, Spirit and Phoenix. Opportunity recently passed 3000 Sols of continuous operations.

Two other Mars orbiters, NASA’s Mars Reconnaissance Orbiter and the European Space Agency’s Mars Express, also will be in position to receive radio transmissions from the Mars Science Laboratory during its descent. However, they will be recording information for later playback, not relaying it immediately, as only Odyssey can.

“We began optimising our orbit several months ago, so that Mars Express will have an orbit that is properly “phased” and provides good visibility of MSL’s planned trajectory,” says Michel Denis, Mars Express Spacecraft Operations Manager.

Mars Express has been orbiting the planet since December 2003.


Image Caption: Mars Express supports Curiosity MSL. Credit: ESA

“NASA supported the arrival of Mars Express at Mars in 2003, and, in the past few years, we have relayed data from the rovers Spirit and Opportunity,” says ESA’s Manfred Warhaut, Head of Mission Operations.

“Mars Express also tracked the descent of NASA’s Phoenix lander in 2008 and we routinely share our deep space networks.

“Technical and scientific cooperation at Mars between ESA and NASA is a long-standing and mutually beneficial activity that helps us both to reduce risk and increase the return of scientific results.”

Watch NASA TV online for live coverage of Curiosity landing: mars.jpl.nasa.gov or www.nasa.gov

Ken Kremer

Will Curiosity Look for Life on Mars? Not Exactly…

“Curiosity is not a life detection mission. We’re not actually looking for life and we don’t have the ability to detect life if it was there. What we are looking for is the ingredients of life.”
– John Grotzinger, MSL Project Scientist

And with these words this latest video from NASA’s Jet Propulsion Laboratory begins, explaining what Curiosity’s goal will be once it arrives on Mars on August 5. There will be a lot of media coverage of the event and many news stories as the date approaches, and some of these will undoubtedly refer to Mars Science Laboratory as a “search for life on Mars” mission… but in reality the focus of MSL is a bit subtler than that (if no less exciting.)

But hey, one can always dream

Video: NASA/JPL

Problems with Mars Odyssey Could Impact Telemetry for Curiosity Rover’s Landing

Caption: NASA’s Mars Odyssey spacecraft passes above Mars’ south pole in this artist’s illustration. The spacecraft has been orbiting Mars since October 24, 2001. Image credit: NASA/JPL

The “seven minutes of terror” could stretch into a longer time of trepidation for the hopeful Mars rover team and fans waiting back on Earth to find out if the Curiosity rover has landed safely. A problem with the Mars Odyssey orbiter means there could be a delay in the telemetry relayed to Earth as the Mars Science Laboratory descends and lands on Mars on August 5/6, 2012.

“There’s no impact to landing itself,” said NASA’s Mars exploration program chief Doug McCuistion at a press briefing on Monday. “It’s simply how that data gets returned to us and how timely that data is.”

McCuistion said the Odyssey team is assessing why the orbiter has gone into safe mode several times since early June, as well as having problems with its attitude control system. The glitches possibly could mean the spacecraft may not be in position to track and relay real-time data from MSL as it descends through Mars’ atmosphere and lands, possibly delaying the telemetry to Earth by several hours.

Curiosity’s automated landing sequence won’t be affected; it’s just that the data won’t be sent immediately – and the 14-minute communications lag between Earth and Mars means that the MSL team won’t be getting real-time updates about the rover’s perilous journey anyway; however, now it might be an even longer delay.

Caption: This artist’s concept from an animation depicts Curiosity, the rover to be launched in 2011 by NASA’s Mars Science Laboratory, as it is being lowered by the mission’s rocket-powered descent stage during a critical moment of the “sky crane” landing in 2012. Image Credit: NASA/JPL-Caltech

The rover is scheduled to land at 10:31 p.m. PDT on Aug. 5 (05:31 UTC, 1:31 a.m. EDT on Aug. 6).

Under normal circumstances, it’s a challenge for the orbiters to get in position to welcome another spacecraft to Mars, and provide tracking data and telemetry relay.

“If we were not to do anything, the Mars’ orbiting spacecraft may be on the other side of the planet,” said MSL navigation team chief Tomas Martin-Mur, during a previous interview with UT. “So as soon as we launch, we tell the other spacecraft where we are going to be by the time of entry so they can change their orbits over time, so they will be flying overhead as MSL approaches the planet.”

The orbiters – which also includes NASA’s Mars Reconnaissance Orbiter and ESA’s Mars Express – have been doing special maneuvers to be aligned in just the right place, nearby to MSL’s point of entry into Mars’ atmosphere.

But the glitches for Odyssey means it may not be in the right place.

MRO will be attempting to image the rover as it descends and lands — with possible hopes of catching the rover as it is descending on the “sky-crane” landing system — but MRO can only record data for later playback, whereas Odyssey could provide immediate relay. Mars Express won’t be aligned to see the last minute of flight, McCuistion said.

The Odyssey orbiter put itself in the precautionary, Earth-pointed status called safe mode on July 11, as it finished a maneuver adjusting, or trimming, its orbit. Odyssey’s computer did not reboot, so diagnostic information was subsequently available from the spacecraft’s onboard memory. Based on analysis of that information, the mission’s controllers sent commands yesterday morning taking Odyssey out of safe mode and reorienting it to point downward at Mars.

“We are on a cautious path to resume Odyssey’s science and relay operations soon,” said Gaylon McSmith, Odyssey project manager. “We will also be assessing whether another orbit trim maneuver is warranted.”

The landing is one of the most perilous times for a rover. “Those seven minutes are the most challenging part of this entire mission,” said Pete Theisinger, MSL’s project manager. “For the landing to succeed, hundreds of events will need to go right, many with split-second timing and all controlled autonomously by the spacecraft. We’ve done all we can think of to succeed. We expect to get Curiosity safely onto the ground, but there is no guarantee. The risks are real.”

We’ll provide updates as to Odyssey’s status. Here’s a look at the seven minutes of terror MSL will experience:

Sources: JPL, NASA

Curiosity and the Issue of Planetary Protection

Curiosity at Centre of Attention During Testing Image Credit: NASA /JPL - Caltech

Curiosity at Centre of Attention During Testing Image Credit: NASA /JPL – Caltech

There have been many reports about the possibility of NASA’s Curiosity rover contaminating Mars with microbes from Earth once it lands on the Red Planet in August. The wheels, the landing procedure and the drill bits have all come under scrutiny. But what are the concerns and what safeguards are there to prevent contamination from this or other missions?

In 1967 the United Nations drew up the ‘Treaty on Principles Governing the Activities of States in the Exploration and Use of Outer Space, Including the Moon and Other Bodies.’ All countries which sign up to the treaty “shall pursue studies of outer space, including the moon and other celestial bodies, and conduct exploration of them so as to avoid their harmful contamination.” Every mission is given a category (I,II,III,IV or V) depending on whether it is a flyby, orbiter, lander, or Earth return mission, whether its destination is a planet, moon, comet, or asteroid and whether the destination could provide clues about life or have the potential to support Earth life. So for instance Cassini is a catagory II mission, Curiosity is classed as a IVc mission.

Every stage of a mission is carefully monitored. From construction in a sterile clean room with laminar-air-flow systems, pressurized microbial barriers and personnel wearing hoods, masks, surgical gloves, booties and protective suits called bunny suits. Components and entire spacecraft are sterilized using dry heat microbial reduction, by being enclosed in a bioshield (like a large casserole dish) and baked them in an oven at 111.7 degrees Celsius for 30 hours. For more sensitive components a low-temperature process is used. Components are placed in a vacuum and hydrogen peroxide is injected into the sterilization chamber to establish a specified vapor concentration. Thousands of samples are taken at every stage of construction and tested for spore-forming organisms, for example the Viking mission in 1975 tested more than 6000 samples in total.

Three issues have arisen with the Curiosity rover. During the landing procedure a parachute and thrusters will slow the descent before the ‘sky crane’ lowers the rover, its wheels making direct contact with the surface. Previous rovers have waited on landing platforms for days before their wheels made contact with the surface and in tests it has been shown that even a few hours exposure to Martian levels of ultraviolet can kill between 81 and 96 per cent of bacteria that may be present. So once Curiosity lands it will probably need to remain stationary for some days to minimize the risk of contamination from its wheels.

Another issue arose last year, after launch, when it was realized that a step in the planetary protection measures wasn’t adhered to during the manufacture of the rover’s drill bits. These were meant to arrive at Mars inside a sterile box, but the box was opened and the bits tested for contamination and one of the bits was attached to the drill head. This procedure strayed from earlier agreed-to protocols. The drills have now become another cause concern as it has been found that Teflon and molybdenum disulfide from seals within the drill assembly could rub off and mix in to contaminate samples excavated during operation, making the samples more difficult to analyze. The MSL team are looking at ways to work around the problem, these could include running the drill on a slower, less percussive setting or dispensing with the drill altogether and relying on Curiosity’s scoop to take soils soil samples and using the rover’s wheels to roll over and break open rocks.

This all serves to highlight the importance of the planetary protection treaty to ensure we do everything possible to reduce the risk of contaminating other worlds and of compromising any data we return.

Find out more at NASA’s Office of Planetary Protection

Engineers Able to Narrow Landing Ellipse for Curiosity Rover

This image shows changes in the target landing area for Curiosity, the rover of NASA's Mars Science Laboratory project. The larger ellipse was the target area prior to early June 2012, when the project revised it to the smaller ellipse centered nearer to the foot of Mount Sharp, inside Gale Crater. Image Credit: NASA/JPL-Caltech/ESA/DLR/FU Berlin/MSSS

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Engineers for the Mars Science Laboratory Curiosity rover have now zeroed in to a more precise landing ellipse, now aiming for a landing spot that is closer to where the scientists ultimately want to be, the foot of Mount Sharp in the center of Gale Crater. It was possible to adjust landing plans because of increased confidence in precision landing technology.

“We’re trimming the distance we’ll have to drive after landing by almost half,” said Pete Theisinger, Mars Science Laboratory project manager at NASA’s Jet Propulsion Laboratory. “That could get us to the mountain months earlier.”

The layers of rock and sediments located in the mountain are the prime location for research with the rover.

Curiosity is scheduled to land at approximately 10:31 p.m. PDT Aug. 5 (1:31 a.m. EDT, Aug. 6). Following checkout operations, Curiosity will begin a two-year study of whether the landing vicinity ever offered an environment favorable for microbial life.

Theisinger and other mission leaders described the target adjustment during an update to reporters on Monday, June 11, about preparations for landing and for operating Curiosity on Mars.

A June 2012 revision of the landing target area for Curiosity, the big rover of NASA's Mars Science Laboratory mission, reduces the area's size. It also puts the center of the landing area closer to Mount Sharp, which bears geological layers that are the mission's prime destination. Image Credit: NASA/JPL-Caltech/ESA/DLR/FU Berlin/MSSS

The landing target ellipse had been approximately 20 kilometers wide by 25 kilometers long (12 miles wide and 16 miles long). Continuing analysis of the new landing system’s capabilities has allowed mission planners to shrink the area to approximately 7 by 20 kilometers (4 by 12 miles), assuming winds and other atmospheric conditions are as predicted.

Even with the smaller ellipse, Curiosity will be able to touch down at a safe distance from steep slopes at the edge of Mount Sharp.

“We have been preparing for years for a successful landing by Curiosity, and all signs are good,” said Dave Lavery, Mars Science Laboratory program executive at NASA. “However, landing on Mars always carries risks, so success is not guaranteed. Once on the ground we’ll proceed carefully. We have plenty of time since Curiosity is not as life-limited as the approximate 90-day missions like NASA’s Mars Exploration Rovers and the Phoenix lander.”

Since the spacecraft was launched in November 2011, engineers have continued testing and improving its landing software. Mars Science Laboratory will use an upgraded version of flight software installed on its computers during the past two weeks. Additional upgrades for Mars surface operations will be sent to the rover about a week after landing.

Other preparations include upgrades to the rover’s software and understanding effects of debris coming from the drill the rover will use to collect samples from rocks on Mars. Experiments at JPL indicate that Teflon from the drill could mix with the powdered samples. Testing will continue past landing with copies of the drill. The rover will deliver the samples to onboard instruments that can identify mineral and chemical ingredients.

“The material from the drill could complicate, but will not prevent analysis of carbon content in rocks by one of the rover’s 10 instruments. There are workarounds,” said John Grotzinger, the mission’s project scientist at the California Institute of Technology in Pasadena. “Organic carbon compounds in an environment are one prerequisite for life. We know meteorites deliver non-biological organic carbon to Mars, but not whether it persists near the surface. We will be checking for that and for other chemical and mineral clues about habitability.”

source: JPL