Curiosity isn’t expected to drill its first drill hole in a Mars rock for about another month or two, according to Rob Manning, the Mars mission’s chief engineer.
Curiosity and its parachute were spotted by NASA’s Mars Reconnaissance Orbiter as Curiosity descended to the surface on 0500 UTC 08-06-12. (Image: NASA/JPL-Caltech/Univ. of Arizona)
A camera aboard Curiosity itself took a sequence of self-portraits of its trip through the Martian atmosphere as well.
According NASA, the Mars Descent Imager (MARDI) snapped over 1,500 images which are being stored within Curiosity’s onboard memory banks. When those images are put together at the highest resolution, they should produce a video showing the rover’s descent from the time its heat shield was released, all the way until it touched down on Mars.
This stop-motion video shows 297 frames from the Mars Descent Imager aboard NASA’s Curiosity rover as it descended to the surface of Mars. (Video: NASA/JPL-Caltech)
Until we get that detailed video of Curiosity’s descent and touchdown, we’ll have to be satisfied with 297 color, low-resolution images the rover recently beamed back to Earth.
This image taken by Curiosity shows Mars’ Mount Sharp. The rover’s shadow can also be seen. (Image: NASA/JPL-Caltech)
“The image sequence received so far indicates Curiosity had, as expected, a very exciting ride to the surface,” says Mike Malin from Malin Space Systems in San Diego, the imaging scientist for the Mars mission. “But as dramatic as they are, there is real other-world importance to obtaining them. These images will help the mission scientists interpret the rover’s surroundings, the rover drivers in planning for future drives across the surface, as well as assist engineers in their design of forthcoming landing systems for Mars or other worlds.”
Other activities planned for the Curiosity today include setting up its high-gain antenna, collecting science data from the system’s Radiation Assessment Detector and Rover Environmental Monitoring Station instruments, as well as picking up additional imagery of its surroundings.
This artist’s concept shows the sky crane maneuver during the descent of NASA’s Curiosity rover to the Martian surface. (Image: NASA/JPL-Caltech)
A close-up view of a South American scarab dung beetle (Oxysternon conspicillatum) (Photo: J. Mark Rowland/Douglas J. Emlen/Courtesy: National Science Foundation)
From the Hubble Space Telescope – Star Cluster R136 bursts out (Photo: NASA, ESA, & F. Paresce (INAF-IASF), R. O’Connell (U. Virginia), & the HST WFC3 Science Oversight Committee)
Engineers checking out the Inflatable Reentry Vehicle Experiment (IRVE-3) at NASA’s Langley Research Center in Hampton, Virginia (Photo: NASA Langley/Sean Smith)
A fluorescent micrograph capturing the presence of bacteria (shown in green) on the surface of an emerging lateral root of the Arabidopsis, a small flowering plant related to cabbage and mustard (Photo: Sarah Lebeis/University of North Carolina)
As seen through a window in the Cupola, the International Space Station’s Canadarm2 grapples the unpiloted Japan Aerospace Exploration Agency (JAXA) H-II Transfer Vehicle (HTV-3). (Photo: NASA)
From NASA’s Chandra X-ray Observatory – X-rays From a young supernova remnant (Image: X-ray: NASA/CXC/STScI/K.Long et al., Optical: NASA/STScI)
A new amphibian species, the ‘Mr. Burns Beaked Toad’ (Credit: USFWS)
An aurora borealis visible in the northern sky over Merritt Reservoir in Valentine, Nebraska (Photo: Howard Edin/Courtesy: National Science Foundation)
Scientists Hope Rover Will Discover If Life Exists on Mars
Artist concept of NASA’s Mars Science Laboratory Curiosity rover, a mobile robot for investigating Mars’ past or present ability to sustain microbial life. (Image: NASA/JPL-Caltech)
The Curiosity rover carries the most sophisticated payload of scientific equipment ever used on Mars’ surface. It’s 10 times the size of earlier Mars rovers, the size as a Sports Utility Vehicle (SUV) rather than the golf cart size of previous rovers. Scientists hope Curiosity will help unlock the mystery of whether life could exist on the red planet.
So far, the Mars mission is on track but its biggest challenges will come when the spacecraft carrying Curiosity executes its entry, descent and landing on Mars. The procedure is so complex mission team members refer to it as “seven minutes of terror.”
Rob Manning, the Mars mission’s chief engineer, says setting Curiosity safely on Mars is the culmination of about a decade’s worth of “thinking, designing and building, involving thousands of people” from around the world.
Artist’s concept of Mars Science Laboratory entry, descent and landing (the 7 minutes of terror’). (Image: NASA/JPL-Caltech)
The Mars Science Laboratory mission is the first of its kind, according to Manning. Although there have been a number of missions to Mars, Curiosity will be the first rover to robotically explore; drilling into rock and performing geochemistry, to gain a better understanding of the chemistry of Mars.
The work performed by Curiosity is expected to allow scientists to learn more about the early history of Mars and whether planet may have, at one time, been habitable for life. Other exploratory missions have shown Mars was a very wet planet.
Although a smaller Mars rover named Opportunity is still working, sending back valuable observational data after more than eight years on the red planet, Manning says Curiosity alone will allow scientists to gather and analyze data on the microscopic, chemical composition of Mars through the vehicle’s advanced on board geochemistry laboratory.
The Mars mission scientists also hope to learn about Mars’ environmental conditions on a microscopic scale, since Curiosity’s drilling function allows it to gather samples from a much earlier time in the planet’s history.
Artist’s conception of Curiosity using the rover’s ChemCam instrument to identify the chemical composition of a rock sample on the surface of Mars. (Image: NASA/JPL-Caltech)
Data gathered from other rovers suggests Mars has water underground. Scientists believe that water was on the surface long enough to chemically alter rock and that the planet has a rich water-based history. Mission scientists now want to determine whether Martian water was around long enough for conditions to sustain life and for life itself to have evolved.
“If we can find signs that Mars was a habitable place and, even more excitingly, if we can find residue of life on Mars in the form of complex organic compounds, we might be able to say something about how life is not ubiquitous on this planet,” says Manning. “In every crack and every crevice of this planet you will find life, maybe Mars itself is the same way, and maybe life got started there too.”
Once safely on the ground, Curiosity won’t move from its landing spot for about five days, to allow the engineers on Earth to make sure the surface directly beneath the rover’s wheels doesn’t present an immediate hazard.
Manning doesn’t expect Curiosity to drill its first hole in a Mars rock until a month or two after landing.
According to NASA, the Mars Science Laboratory’s primary mission will last one Martian year, or about 687 Earth days, surviving at least one Martian winter in the process.
Star Trek’s Captain Kirk, actor William Shatner, narrates this video about NASA’s Curiosity rover, from its entry and descent through the Martian atmosphere to its landing and exploration of the Red Planet. (Video: NASA Television)
Rob Manning joins us this weekend on the radio edition of ‘Science World’. He talks about the Curiosity, the Mars Science Laboratory mission and what scientists hope to learn from its work. Check out the right column for scheduled air-times or listen to the interview with Ms. Wallace below.
[audio://blogs.voanews.com/science-world/files/2012/07/080312-Science-World-Interview-Curiosity-Rob-Manning-Mars-Science-Laboratory-Chief-Engineer-at-JPL-080312.mp3|titles=One On One – Rob Manning – Mars Science Laboratory mission – NASA/JPL – Web]
