Tag: HiRISE camera

News From Mars: Curiosity and Opportunity On the Move

marsMars has been quite the source of news in recent weeks. And perhaps its the fact that I got to witness some truly interesting astronomical phenomena yesterday – i.e. Sunspots through a telescope – but all of them seem to have caught my attention at once. And given their importance to the ongoing exploration of Mars and our Solar System, I would be remiss if I didn’t pass them on.

The first bit of news began late last month, when the High Resolution Imaging Science Experiment (HiRISE) camera on the Mars Reconnaissance Orbiter snapped this image of the Curiosity rover as it made its way through the “Glenelg” area of Gale Crater. The rover appeared as a little more than a blueish dot in the picture, but much more visible was the rover’s tracks.

curiosity_hirise_tracks This unique photo was made possible thanks to a little maneuvering and a some serious alignment. Basically, the folks working at the Mars Science Laboratory were able to bring the Mars Reconnaissance Orbiter (MRO) into position between the Sun and curiosity, bringing the Sun, MRO, and the rover on the surface were in a near-perfect alignment.

HiRISE principal investigator Alfred McEwen addressed the photos on the HiRISE website and explained how it was all made possible:

The rover tracks stand out clearly in this view, extending west to the landing site where two bright, relatively blue spots indicate where MSL’s landing jets cleared off the redder surface dust. When HiRISE captured this view, the Mars Reconnaissance Orbiter was rolled for an eastward-looking angle rather than straight downward. The afternoon sun illuminated the scene from the western sky, so the lighting was nearly behind the camera. Specifically, the angle from sun to orbiter to rover was just 5.47 degrees.

Curiosity has since moved on and is now heading towards the large mound in Gale Crater officially named Aeolis Mons (aka. Mount Sharp).

curiosity_roadmapWhich brings us to the second news item in this week’s Mars bulletin. It seems that since July 4th, after finishing up a seven months survey in Yellowknife Bay, Curiosity has achieved a long-distance driving record as it made its way to Mount Sharp. This took place on Saturday July 21st (Sol 340), when Curiosity drove a distance of 100.3 meters (109.7 yards) in a single day.

To give you some perspective, that’s the length of a football field (at least in the US), a distance that is without equal since she first landed inside the Gale Crater nearly a year ago. The previous record for a one-day drive was about half a football field – 49 meters (54 yards) – and was achieved on Sept. 26, 2012 (Sol 50), roughly seven weeks after Curiosity made its tense, nail-biting landing.

Curiosity-departs-Glenelg-Sol-324_2a_Ken-Kremer--580x291Paolo Bellutta, a rover planner at NASA’s Jet Propulsion Laboratory, Pasadena, Calif, explained what made the feat possible in a statement:

What enabled us to drive so far on Sol 340 was starting at a high point and also having Mastcam images giving us the size of rocks so we could be sure they were not hazards. We could see for quite a distance, but there was an area straight ahead that was not clearly visible, so we had to find a path around that area.

A combination of increased experience by the rover’s engineers and a series of intermediate software upgrades have also played a key role in getting Curiosity on its way to the 5.5 kilometer (3.4 mile) high Mount Sharp. This is expected to improve even more as soon as new driving software called autonomous navigation (or autonav) finishes development and is incorporated.

mountsharp_galecraterFollowing another lengthy drive of 62.4 meters (68.2 yards) on Wednesday, July 23 (Sol 342), the mission’s total driving distance  stands at 1.23 kilometers (0.81 mile) so far. But Mount Sharp still lies about another 8 km (5 miles) away at this point, so we can be expect to be hearing plenty from the rover between now and when it arrives.

For the record, it has already been discovered that the mountain contains vast caches of minerals that could potentially support a habitable environment. So when Curiosity arrives, we can expect another string of exciting finds!

Opportunity-nears-Solander-Point-Sol-3374-N1-crop_Ken-Kremer-580x309And it is this subject of mountain goals which brings me to the last, but by no means least, of the Martian updates. While Curiosity has been making its way towards Mt. Sharp to conduct research on potentially habitable environments, Opportunity is just days away from reaching Solander Point, another Martian mountain which NASA seeks to learn more about.

This comes on the heels of the rover’s ten year, ongoing mission that was only ever expected to last ninety days. According to an update from Ray Arvidson earlier today, the mission’s deputy principal scientific investigator from Washington University in St. Louis, the rover is now just 180 meters away from the new mountain.

opportunity_roadmapAs NASA had previously stated, Solander Point represents ‘something completely different’ for the rover, being the first mountain it will ever climb. What’s more, the mountains mineral wealth may possess the key chemical ingredients necessary to sustain Martian life forms, and the area exhibits signatures related to water flow.

In many ways, you could say Solander Point represents a chance for the Mars Science Laboratory to find the elusive “organic molecules” they’ve been searching for since Curiosity first landed. And if it’s the veteran rover that finds the first hard evidence of their existence, it would be quite the feather in the Opportunity team’s cap.

opportunity_bdayBut before moving onto the first leg of ascent, Arvidson explained that the rover will be making a brief pause in its current location to conduce some exciting experiments. Thanks to observations made of the area by the Mars Reconnaissance Orbiter with its CRISM instrument (Compact Reconnaissance Imaging Spectrometers for Mars), the rover will be conducting some on-the-spot analysis to see if there is indeed evidence of water.

This past spring, Opportunity made the historic discovery of clay minerals and a habitable environment on a low hill called Cape York, the rover’s prior stop along the rim of Endeavour Crater. Solander was selected as the robot’s next destination because it also offers a goldmine of scientific data. Another reason was because its north facing slopes will be a boon to Opportunity’s solar wings, ensuring it more power before Martian winter sets in.

opportunity_missionmapBut since Opportunity is currently sitting on a healthy supply of power and has some time before the onset of her 6th Martian winter, the team decided to take a small detour to the southeast and spend several days exploring the area for more evidence of water-bearing minerals.

If successful, this will be yet another accomplishment for the rover during its long tenure of service to NASA. Today marks the 3380th day of continuous service for the rover – aka. Sol 3380 – a mission which has resulted in numerous scientific finds, over 182,000 images, and a driving distance of roughly 38 kilometers (23.6 miles). This, as already mentioned, puts Opportunity in the top spot for the longest distance traveled on another planet.

Yes, it seems that the Red Planet is certainly doing all it can to keep explorers and scientists intrigued. No telling what we might learn between now and the point when manned missions take place, and human astronauts are able to see the surface and study its mysteries close up. Personally, I’m hoping for signs of existing supplies of water, not to mention those tricky organic molecules. If settlement and terraforming are ever to take place, we need to know we’ve got something to work with!

Sources: universetoday.com, (2) , (3), nasa.gov, space.com

More News from Mars… Lots More!

marsIt’s a good thing I’ve come down with a cold and have little to do but sit at my computer. Because in the last week, some very interesting news stories have been piling up that just scream for recognition. And wouldn’t you know it, more than a few have to do with our big red neighbor Mars, that world many human beings will one day think of as home.

The first story comes to us from the Siding Spring Observatory in New South Wales, where noted astronomer Robert McNaught recently sighted an new comet. From his observations, the icy interloper appeared to have originated in the Oort Cloud – a hypothetical cloud surrounding the solar system and containing billions of icy planetesimals that were cast out from our Solar System billions of years ago.

Mars_A1_Latest_2014After news of the discovery was released, the astronomers at the Catalina Sky Survey in Arizona looked back over their observations to find “prerecovery” images of the comet dating back to Dec. 8, 2012. These observations placed the orbital trajectory of the comet – now known as C/2013 A1 – through the orbit of Mars on Oct. 19, 2014. This means, in essence, that this comet could very well strike the Red Planet late next year.

Luckily, NASA’s Jet Propulsion Laboratory has run the calculations and indicated that their close approach data suggests the comet is most likely to make a close pass of the Martian surface. And by close, they mean at roughly 0.0007 AU, or approximately 100,000 kilometers (63,000 miles) from the Martian surface. So in all likelihood, Curiosity and Opportunity will be safe from a serious impact that could turn them into scrap metal!

But of course, predicting its exact trajectory at this time is subject to guess work, and ongoing observations will be needed. No doubt, the predictions will be refined a the next 20 months go by, and we’ll know for sure if this comet plans to miss Mars completely, or slam head-on into the surface at 200,000 km/h (126,000 mph).

Source: news.discover.com, astroblogger.blogspot.ca

Mars_curiosity_drillingThe second bit of news comes to us from the good-ole Curiosity Rover! Roughly four weeks after conducting the first drilling operation into the Martian surface, the Rover ate its first sample of the grey dust that resulted. The delivery of the two aspiring-sized tablets of dust took place on Feb. 22nd and 23rd respectively after the robotic arm delivered them into the rover’s Chemistry and Mineralogy (CheMin) and Sample Analysis at Mars (SAM) laboratories for analysis. Results expected in two weeks!

Among other things, the results from the analysis are expected to give clues as to what the color change between the red surface and the grey interior means. One theory is that it might be related to different oxidations states of iron that could potentially inform us about the habitability of Mars inside the rover’s Gale Crater landing site.

Living-Mars.2At the same time, the Mars Science Laboratory team expects to find further evidence of what life was like in previous geological eras. The Curiosity team believes that the area inside the Gale Crater, known as Yellowknife Bay, experienced repeated exposure to flowing liquid water long ago when Mars was warmer and wetter – and therefore was potentially more hospitable to the possible evolution of life.

The rover will likely remain in the John Klein area for a month or more to obtain a more complete scientific characterization of the area which has seen repeated episodes of flowing water. Eventually, the six-wheeled mega rover will set off on a year long trek to her main destination: the sedimentary layers at the lower reaches of the  5 km (3 mile) high mountain named Mount Sharp.

Source: universetoday.com

mars_hieroglyphsAnd last, but not least by any stretch of the imagination, is the discovery of “hieroglyphs” on the Martian surface. While they might appear like ancient glyphs to the untrained eye, they are in fact evidence of past subsurface water. The images were caught by the HiRISE camera on the Mars Reconnaissance Orbiter as it passed the surface area known as Amazonis Planitia.

Known as ‘rootless cones,’ these geological features are the result of an explosive interaction of lava with ground ice or water contained within the regolith beneath the flow. Vaporization of the water or ice when the hot lava comes in contact causes an explosive expansion of the water vapor, causing the lava to shoot upward, creating what appears to be a button hole on the surface.

rootlessConesIn the past, Mars scientists have used geological patterns on Earth to make sense of similar ones found on Mars. For example, when the Curiosity Rover discovered veins of hydrated calcium in the rock surface in the Gale Crater, they compared them to similar patterns found in Egypt to determine that they were the result of long-term exposure to water flows. In this case, the rootless cones found in Amazonis Planitia are comparable to those found in Iceland’s Laki Lava Flow (as seen above).

According to Colin Dunas, from the US Geological Survey, the cones are rather large and most likely very old:

“The cones are on the order of a hundred meters across and ten meters high. The age of these specific cones isn’t known. They are on a mid- to late-Amazonian geologic unit, which means that they are young by Martian standards but could be as much as a few hundred million to over a billion years old.”

terraformingOnly time will tell if any subsurface water is still there, and hence usable by future teams of terraformers and settlers. According to Dundas, the odds are not so good of that being the case. Given the surface depth at which the ice was found, not to mention that at the low latitude at which it was found (22 degrees north), shallow ground ice is unstable. Dundas added that since ice stability varies as the obliquity changes, it’s even possible that ice has come and gone repeatedly since the lava erupted.

Too bad. That could have come in really handy for hydroponics, fuel cells, and even restoring surface water to the planet. Guess future generations of Martians will just have to look for their ground and irrigation water elsewhere, huh? Just another challenge of converting the Red Planet to a green one, I guess 😉

Stay tuned for more news Mars. As it stands, there’s plenty to be had! Stick around!

Source: hirise.lpl.arizona.edu, universetoday.com