Throughout the summer, six people participated in an experiment designed to test how people will deal with the physical and psychological strangeness of a manned space journey. Known as the “Hawaii Space Exploration Analog and Simulation” (HI-SEAS) study, the research took place on a desolate slope of an abandoned quarry in Hawaii, 8,000 feet above sea level.
Here, the volunteers lived in a two-story geodesic dome and put on a full space suit to venture outside. Their communications were limited, their shower time rationed, and each spent much of their time conducting individual “space” experiments. But most importantly, they were eating food fit for a Mars astronaut. This was the main purpose of the experiment, testing the menu that manned missions to Mars will have to offer.
For years now, scientists have been trying to find ways to make astronaut food more palatable. In space, the food is either dehydrated and requires water and heat to process, or is rendered in liquid form that has to be drunk right out of the package. But on Mars, where there would be gravity, astronauts could actually cook their own food from “shelf-stable” ingredients.
The goal of the HI-SEAS study, run by investigators at the University of Hawaii at Manoa and Cornell University, has been to figure out the best strategies for nourishing Mars astronauts. On any long and isolated mission, especially on one as long as a hypothetical Mars mission. “menu fatigue” is a real danger. Astronauts need to consume a set amount of calories a day, otherwise they might lose body mass and bone density.
Lemon Dill Pasta Salad
For the sake of testing the menu, the mission relied on a six-member crew of scientific-minded professionals who kept detailed logs of their food adventures. They filled out smell, taste, and appearance questionnaires for each meal; weighed each food item; tracked water consumption, cooking and cleanup time; and even monitored their sense of smell to see if food boredom had any physiological effects.
Another fun aspect was that they also tested crowdsourced recipes submitted by the public. Each recipe was limited to using the list of ingredients available. There was “Cajun Style Spam Jambalaya” and “Oatmeal Thickened Beef Stew” for dinner, “Blueberry Lemon Cornmeal Pancakes” for breakfast, and even a spicy veggie sushi as an appetizer.
“Dark Matter” cake
Kate Greene, a science and technology journalist on the mission, had this to say about the menu:
I’ve enjoyed so many meals here, actually. A quinoa salad, breakfast tacos, borscht, beef tagine, and all the breads we make with our bread maker… We’ve also had cakes and puddings and pies, grilled cheese sandwiches and soups like seafood chowder.
With today’s technology, it could take as long as 300 days to even get there. But even with fully-stocked shelves, life on a Mars mission would still be a major challenge. In addition to fighting menu boredom, there was also the issue of regular boredom. Confined to their shelters and forced to wear space suits to go outside, the “astronauts” began to miss the everyday activities they used to take for granted.
As Greene indicated, she came to miss such things as walking about outside, biking, and swimming, and gained a new appreciation for her old life:
Something I realized about my day-to-day life on Earth is that it’s full of novelty. I see new people all the time and I go to different places. In the habitat, novelty has been a lot harder to come by, and it was subtle when I found it–a new recipe, a different way to arrange the furniture, or someone saying something completely out of character. When I noticed these slight changes, my joy and excitement was embarrassingly disproportionate.
On August 13th, Greene and her five colleagues emerged into the daylight without a spacesuit for the first time in months. After a media event and a debrief with the principal researchers on the NASA-funded project, they continued to sift through all of their research data, which ranged from scientific research, their food study, and even a record of their sleep cycles.
All of this information is likely to be very useful in coming years and decades. Back in August, on the one-year anniversary of the Curiosity Rover’s landing on Mars, NASA chief Charles Bolden said he believed that human footprints would follow in its path, and 2030 remains the projected date for putting those boots on the Red Planet.
It’s one of Jupiter’s four largest moons, named the Jovians by the famed astronomer – Galileo Galilee – who first discovered them. And from all outward appearances, the moon is an icy, inhospitable place, with surface temperatures never reaching above -160º C (-256º F). Yet, beneath that frozen outer shell is believed to be a liquid, saltwater ocean, one that draws warmth from its orbit around Jupiter.
If this should indeed be the case, then Europa would be about the best candidate for extraterrestrial life in the Solar System, albeit in microbial form. For decades now, NASA has been working under that assumption and preparing for the day that it might be able to send an expedition or probe to confirm it. And it now seems that that day may be on the horizon.
According to NASA, this would likely take the form of a robot lander. Much like Curiosity, Opportunity, and other robotic research vehicles, it would packed with a variety of sensors and analytical equipment. But of course, the nature of that equipment would be specifically tailored to answer a series of unknowns pertaining to Europa itself.
Overall, the lander would have three priorities: discover the makeup of minerals and organic matter present on the moon; examine the geophysics of the ice and the ocean underneath; and determine how the geology looks (and therefore how it might have evolved) at a human scale on the surface. Basically, it would all boil down to looking at chemistry, water and energy – in other words, the conditions necessary for life.
And though NASA has not announced any official dates, it has begun to speak of the idea an indication of intent. A new article by NASA scientists published in the peer-reviewed journal Astrobiology entitled Science Potential from a Europa Lander set out their research goals in more detail, and speculated how they might be practically achieved.
One area of focus would be Europa’s distinctive linear surface cracks which are believed to be the result of tidal forces. Europa’s eccentric orbit about Jupiter causes very high tides when the moon passes closest to the gas giant, so it is thought that this process would generate the heat necessary for simple life to survive. NASA thinks the cracks could contain biological makers, molecules indicating the presence of organic life, which have come from the ocean.
But of course, plotting a mission is not as simple as simply launching a robot into space. To ensure that such a mission would maximize returns requires that a “scientifically optimized” landing site be identified, and to do that, Europa’s surface must be thoroughly surveilled. Thus far, the little we know and think about Europa is based on a handful of flybys by Voyager 2 in the 70s and the Galileo probe in the 90s.
Lead author Robert Pappalardo of NASA’s Jet Propulsion Laboratory summed up the situation as follows:
There is still a lot of preparation that is needed before we could land on Europa, but studies like these will help us focus on the technologies required to get us there, and on the data needed to help us scout out possible landing locations. Europa is the most likely place in our solar system beyond Earth to have life today, and a landed mission would be the best way to search for signs of life.
At the present time, NASA’s exploratory itinerary is quite packed. In addition to wanting to tow an asteroid closer to Earth to study it, launching two more rovers to Mars, constructing a settlement on the far side of the Moon, and conducting a manned mission to Mars, it’s safe to say that a robot lander on Europa won’t be happening for some time.
But of course, the plans are in place and moving forward with every passing year. NASA is certainly not going to pass up a chance to examine one of the Solar Systems best candidates for extra-terrestrial life, and we can certainly expect more deep-space probes to be launched once Cassini is finished shooting pictures of Saturn.
I am willing to bet good money that any future probe sent into the outer reaches of the Solar System will be tasked with taking high-resolution photos of Europa as part of its mission. And from that, we can certainly expect NASA, the ESA, and even the Chinese, Russians and Indians to start talking turkey within our lifetimes.
What do you think? 2035 seem like a safe bet for a Europa lander mission?
Two days ago, the Mars Rover known as Curiosity celebrated a full year of being on the Red Planet. And what better way for it to celebrate than to revel in the scientific discoveries the rover has made? In addition to providing NASA scientists with years worth of valuable data, these groundbreaking finds have also demonstrated that Mars could once have supported past life – thereby accomplishing her primary science goal.
And it appears that the best is yet come, with the rover speeding off towards Mount Sharp – the 5.5 km (3.4 mile) high mountain dominating the center of the Gale Crater – which is the rover’s primary destination of the mission. This mountain is believed to contain vast caches of minerals that could potentially support a habitable environment, thus making it a veritable gold mine of scientific data!
To take stock of everything Curiosity has accomplished, some numbers need to be tallied. In the course of the past year, Curiosity has transmitted over 190 gigabits of data, captured more than 71,000 images, fired over 75,000 laser shots to investigate the composition of rocks and soil, and drilled into two rocks for sample analysis by the SAM & CheMin labs housed in her belly.
On top of all that, the rover passed the 1 mile (1.6 km) driving mark on August 1st. Granted, Mount Sharp (aka. Aeolis Mons) is still 8 km (5 miles) away and the trip is expected to take a full year. But the rover has had little problems negotiated the terrain at this point, and the potential for finding microbial life on the mountain is likely to make the extended trip worthwhile.
But even that doesn’t do the rover’s year of accomplishments and firsts justice. To really take stock of them all, one must consult the long-form list of milestones Curiosity gave us. Here they are, in order of occurrence from landing to the the long trek to Mount Sharp that began last month:
1. The Landing: Curiosity’s entrance to Mars was something truly new and revolutionary. For starters, the distance between Earth and Mars at the time of her arrival was so great that the spacecraft had to make an entirely autonomous landing with mission control acting as a bystander on a 13-minute delay. This led to quite a bit a tension at Mission Control! In addition, Curiosity was protected by a revolutionary heat shield that also acted as a lifting body that allowed the craft to steer itself as it slowed down in the atmosphere. After the aeroshell and heat shield were jettisoned, the rover was lowered by a skycrane, which is a rocket-propelled frame with a winch that dropped Curiosity to the surface.
2. First Laser Test: Though Curiosity underwent many tests during the first three weeks after its landing, by far the most dramatic was the one involving its laser. This single megawatt laser, which was designed to vaporize solid rock and study the resultant plasma with its ChemCab system, is the first of its kind to be used on another planet. The first shot was just a test, but once Curiosity was on the move, it would be used for serious geological studies.3. First Drive: Granted, Curiosity’s first drive test was more of a parking maneuver, where the rover moved a mere 4.57 m (15 ft), turned 120 degrees and then reversed about 2.4 m (8 feet). This brought it a total of about 6 m (20 ft) from its landing site – now named Bradbury Landing after the late author Ray Bradbury. Still, it was the first test of the rover’s drive system, which is essentially a scaled-up version of the one used by the Sojourn and Opportunity rovers. This consists of six 50 cm (20-in) titanium-spoked aluminum wheels, each with its own electric motor and traction cleats to deal with rough terrain.
4. Streams Human Voice: On August 28, 2012, Curiosity accomplished another historical first when it streamed a human voice from the planet Mars back to Earth across 267 million km (168 million miles). It was a 500 kilobyte audio file containing a prerecorded message of congratulations for the engineers behind Curiosity from NASA administrator Charles Bolden, and demonstrated the challenges of sending radio beams from Earth to distant machines using satellite relays.
5. Writes a Message: Demonstrating that it can send messages back to Earth through other means than its radio transmitter, the Curiosity’s treads leave indentations in the ground that spell out JPL (Jet Propulsion Lab) in Morse Code for all to see. Apparently, this is not so much a gimmick as a means of keeping track how many times the wheels make a full revolution, thus acting as an odometer rather than a message system.
6. Flexing the Arm: Curiosity’s robotic arm and the tools it wield are part of what make it so popular. But before it could be put to work, it had to tested extensively, which began on August 30th. The tools sported by this 1.88 m (6.2-ft) 33.11kg (73 lb) arm include a drill for boring into rocks and collecting powdered samples, an Alpha Particle X-ray Spectrometer (APXS), a scooping hand called the Collection and Handling for In-Situ Martian Rock Analysis (CHIMRA), the Mars Hand Lens Imager (MAHLI), and the Dust Removal Tool (DRT).
7. Discovery of Ancient Stream Bed: Curiosity’s main mission is to seek out areas where life may have once or could still exist. Therefore, the discovery in September of rocky outcroppings that are the remains of an ancient stream bed consisting of water-worn gravel that was washed down from the rim of Gale Crater, was a major achievement. It meant that there was a time when Mars was once a much wetter place, and increases the chances that it once harbored life, and perhaps still does.
8. First Drilling: In February, Curiosity conducted the first robot drill on another planet. Whereas previous rovers have had to settle for samples obtained by scooping and scraping, Curiosity’s drill is capable of rotational and percussive drilling to get beneath the surface. This is good, considering that the intense UV radiation and highly reactive chemicals on the surface of Mars means that finding signs of life requires digging beneath the surface to the protected interior of rock formations.9. Panoramic Self Portrait: If Curiosity has demonstrated one skill over and over, it is the ability to take pictures. This is due to the 17 cameras it has on board, ranging from the black and white navigation cameras to the high-resolution color imagers in the mast. In the first week of February, Curiosity used its Mars Hand Lens Imager to take 130 high-resolution images, which were assembled into a 360⁰ panorama that included a portrait of itself. This was just one of several panoramic shots that Curiosity sent back to Earth, which were not only breathtakingly beautiful, but also provided scientists with a degree of clarity and context that it often lacking from images from unmanned probes. In addition, these self-portraits allow engineers to keep an eye on Curiosity’s physical condition.
10. Long Trek: And last, but not least, on July 4th, Curiosity began a long journey that took it out of the sedimentary outcrop called “Shaler” at Glenelg and began the journey to Mount Sharp which will take up to a year. On July 17, Curiosity passed the one-kilometer mark from Bradbury Landing in its travels, and has now gone more than a mile. Granted, this is still a long way from the breaking the long-distance record, currently held by Opportunity, but it’s a very good start.
Such was Curiosity’s first 365 days on Mars, in a nutshell. As it enters into its second year, it is expected to make many more finds, ones which are potentially “Earthshaking”, no doubt! What’s more, the findings of the last year have had an emboldening effect on NASA, which recently announced that it would be going ahead with additional missions to Mars.
These include the InSight lander, a robotic craft which will conduct interior studies of the planet that is expected to launch by 2016, and a 2020 rover mission that has yet to be named. In addition, the MAVEN (Mars Atmosphere and Volatile Evolution) orbiter as just arrived intact at the Kennedy Space Center and will be blasting off to the Red Planet on Nov. 18 from the Florida Space Coast atop an Atlas V rocket.
These missions constitute a major addition to NASA’s ongoing study of Mars and assessing its past, present and future habitability. Between rovers on the ground, interior studies of the surface, and atmospheric surveys conducted by MAVEN and other orbiters, scientists are likely to have a very clear picture as to what happened to Mars atmosphere and climate by the time manned missions begin in 2030.
Stay tuned for more discoveries as Curiosity begins its second year of deployment. Chances are, this year’s milestones and finds will make this past years look like an appetizer or a warm-up act. That’s my hope, at any rate. But considering what lies ahead of it, Curiosity is sure to deliver!
In the meantime, enjoy some of these videos provided by NASA. The first shows Curiosity’s SAM instrument singing “happy birthday” to the rover (though perhaps humming would be a more accurate word):
And check out this NASA video that sums up the rover’s first year in just two minutes:
Yes, the name is a bit of a attention-getter, but when you come to understand the purpose behind Lockheed Martin’s new spacecraft, the description does appear to be quite apt. It’s known as MAVEN, which stands for Mars Atmosphere and Volatile EvolutioN, and it is currently being produced in Lockheed Martin’s Martin Space Systems facility in Denver, Colorado.
People may recall how earlier this year, MAVEN was mentioned as part of the “Going to Mars” campaign. A project that is being organized by the University of Colorado at Boulder’s Laboratory for Atmospheric and Space Physics (CU/LASP), the Martian orbiter will be carrying a DVD featuring the names of everyone who applies, as well as three specially-selected haikus.
However, it is MAVEN’s larger mission which is now the focus of much interest. Later this year, NASA will be launching the orbiter to Mars for the sake of examine the atmosphere and answering some burning questions that remain about the planet. Thanks to evidence provided by Curiosity, Opportunity, and other missions, scientists now know that the Martian surface once boasted conditions suitable for life, including liquid water.
Hence, Maven’s ultimate purpose, which will be will to orbit the planet and examine whether the atmosphere could also have provided life support. Scientists working on the Maven mission want to understand what this atmosphere was like, and the processes that led to its destruction. As Guy Beutelschies, Maven Programme Manager at Lockheed Martin, put it:
What we know from our missions looking at the surface of Mars is that there used to be water there. We can see the outlines of ancient rivers, the shorelines of ancient oceans. But water can’t exist there now – the atmosphere is too thin and too dry, any water would just evaporate or freeze.
So the big question is what happened to Mars’ atmosphere? Short of being able to travel back in time into the Martian past, how would anyone go about tackling these questions with a mission today? Beutelshcies explained it as follows:
[The atmosphere] used to be thicker, warmer, wetter, now it’s thin and dry. How did we get there? In a sense we are building a little bit of a time machine. What we’re doing is understanding the processes.
Just last week, evidence provided by the Curiosity rover supports the theory that Mars may have lost most of its atmosphere billions of years ago. Still, scientists remain skeptical that Mars once had an atmosphere comparable to that of Earth. Today, that atmosphere is roughly one-hundredth the thickness of Earth’s, made up mostly of carbon dioxide and a tiny fraction of water vapor. What little remains is being stripped away by the solar wind.
And unlike Earth, Mars does not have a magnetosphere to protect its atmosphere from being blown away – at least not anymore. Such a fragile, thin band around is now unlikely to support any sort of life, as far as we know. But the atmosphere in the past must have been more substantial to allow the formation of rivers, lakes and oceans.
Bruce Jakosky, the Principal Investigator for Maven who is based at the University of Colorado’s CU/LASP lab in Boulder, claims:
We think that Mars used to have a magnetic field. We see places on the surface that retain some remnant magnetism, they were imprinted when they formed with whatever magnetism was there. We think that some four billion years ago, when the magnetic field turned off, that turn-off of the magnetic field allowed [for the] turn-on of the stripping by the solar wind.
To investigate the processes taking place today, Maven will dip into the Martian upper atmosphere with each orbit, measuring the particles, sampling gases, monitoring the magnetic field and solar wind. Whereas the rovers have looked at the atmosphere from the ground up, MAVEN will look at it from the top down. At this point, both are needed to put together a picture of what’s controlling the Mars environment.
As well as filling in the blanks about Mars’ depleted atmosphere, Maven will also provide clues to the habitability of other planets beyond the solar system. As Jakosky said, the research conducted will have far-reaching implication for our understanding:
In trying to understand the distribution of life throughout the Universe, this is a really important indicator. Understanding the environmental conditions that allow [life] to exist, or don’t allow it to exist, is key to being able to extrapolate elsewhere.
What’s more, understanding what happened to Mars will provide some key insight into the history of our Solar System, and how it went from being a star with two planets that had oceans and atmospheres to just one. Knowing why things continued to operate on Earth, while on Mars they went horribly wrong, is likely to be quite the eye-opener, and make us all thankful we evolved here on Earth.
Mars 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.
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).
Which 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.
Paolo 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.
Following 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!
And 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.
As 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.
But 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.
But 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!
Ever since astronomers first looked up at Mars, they discerned features that few could accurately identify. For many years, speculations about irrigation, canals, and a Martian civilization abounded, firing people’s imaginations and fiction. It was not until more recently, with the deployment of the Viking probe, that Mars’ surface features have come to be seen for what they are.
Thanks several more probes, and the tireless work of rover such as Opptorunity and Curiosity, scientists have been able to amass evidence and get a first hand look at the surface. Nevertheless, they are still hard-pressed to explain everything that they’ve seen. And while much evidence exists that rivers and lakes once dotted the landscape, other geological features exist which don’t fit that model.
However, a recent report from Brown University has presented evidence that snowfall may be one answer. It has long been known that ice exists at the polar caps, but actual snowfall is a very specific meteorological feature, one that has serious implications for early Martian conditions. This is just another indication that Mars hosted an environment that was very much like Earths.
And this is not the first time that snow on Mars has been suggested. In 2008, NASA announced having detected snow falling from Martian clouds, but it was entirely vaporized before reaching the ground. The Brown researchers claim that snowfall in the past, and buildup on the surface leading to melting and runoff, could have created many of the tributary networks observed near tall mountain-ranges.
To back this claim up, the team used a computer simulation from the Laboratoire de Météorologie Dynamique called the Mars global circulation model (GCM). This model compiles evidence about the early composition of the red planet’s atmosphere to predict global circulation patterns. And since other models predict that Mars was quite cold, the program indicated the highest probability of snowfall over the densest valley systems.
Lead researcher Kat Scanlon also relied on her background in orographic studies (science for “studying mountains”) in Hawaii to arrive at this hypothesis. This includes how tall mountains lead to divergent weather patterns on either side, with warm, wet conditions one and cold, dry ones on the other. NASA’s Curiosity rover also was intrinsic, thanks to recent information that might explain why Mars no longer displays this kind of behavior.
In short, Curiosity determined that the planet is losing its atmosphere. It has taken detailed assays of the current atmosphere, which is almost entirely carbon dioxide and about 0.6% the pressure of Earth’s at sea-level. More notably, it has used its ability to laser-blast solid samples and analyze the resulting vapor to determine that Mars has an unusually high ratio of heavy to light isotopes — most importantly of deuterium to hydrogen.
The main explanation for this is atmospheric loss, since light isotopes will escape slightly more quickly than heavy. Over billions of years, this can lead to non-standard isotope levels the show a loss of atmosphere. One major theory that might explain this loss say that about 4.2 million years ago Mars collided with an object about the size of Pluto. An impact from this body would have caused a huge expulsion of atmosphere, followed by a slow, continued loss from then on.
All of this plays into the larger question of life on Mars. Is there, or was there, ever life? Most likely, there was, as all the elements – water, atmosphere, clay minerals – appear to have been there at one time. And while scientists might still stumble upon a Lake Vostok-like reserve of microbial life under the surface, it seems most likely that Mars most fertile days is behind it.
However, that doesn’t mean that it can’t once again host life-sustaining conditions. And with some tweaking, of the ecological engineering – aka. terraforming – variety, it could once again.
NASA’s Opportunity Rover is a special kind of vehicle. Not only did it set the record for longest distance driven on another world and discover the most compelling evidence for life on Mars thus far, it also surpassed its 90 day mission by a grand total of 3560 days, as of this past July 7th. In other words, the Opportunity Rover just celebrated its tenth anniversary, and people all over the world are marking the occasion by acknowledging the rover’s many contributions.
These include discovering the first meteorite found outside of Earth, a temperature profile of the Martian atmosphere, and uncovering a series tiny, iron-rich spheres known as “blueberries” that hinted at a time when Mars had water. In fact, Opportunity’s most important discovery may have come just last month.
This consisted of a rock that proves that Martian water was once drinkable, which in turn suggests strongly that life could once have thrived there. On top of that, it captured some amazing photos, long before Curiosity was sending back its hefty batch of panoramas. But of course, Opportunity had its share of trials and tribulations as well.
Foremost amongst these was the two months back in 2005 that it spent spent in a sand dune before its operators were able to wriggle it free centimeter by centimeter. And on the rover’s second day on Mars, it also experienced some shoulder joint problems, which proved to be the first of many, many mechanical problems.
And yet, all of that seems worth it now. After being eclipsed by its larger, more recent arrival – the Curiosity Rover – Opportunity has battled back with its incredible longevity. Who’s to say how much longer the little rover that could will remain in operation? And who’s to say what it will uncover. At this rate, its doesn’t seem unlikely that it will beat its cousin to the punch of finding the Holy Grail – organic particles on Mars!
And be sure to enjoy this video look-back at Opportunity produced by Space.com:
Ever since the Opportunity and Curiosity Rovers began their research stint on the red planet, evidence has been pouring in that indicates that the planet once supported life. And now, by examining the compositions of Martian meteorites found on Earth and data provided by the Mars rovers, Scientists from the Department of Earth Sciences at the University of Oxford have determined that the planet once boasted an oxygen-rich atmosphere.
The key determinant was the fact that the Martian surface rocks were five times richer in nickel than the meteorites found on Earth, a find which cast doubt on whether the meteorites were typical volcanic products. Whilst it is possible that the geological composition of Mars varies immensely from region to region, the team believes that it is more likely that the differences arise through a process known as subduction – in which material is recycled into the interior.
The scientists suggest that the Martian surface was oxidized very early in the history of the planet and that, through subduction, this oxygen-rich material was drawn into the shallow interior and recycled back to the surface during eruptions 4 billion years ago. The meteorites, by contrast, are much younger volcanic rocks that emerged from deeper within the planet and so were less influenced by this process.
As Professor Bernard Wood, the senior author of a study that appeared in Nature magazine, put it:
What we have shown is that both meteorites and surface volcanic rocks are consistent with similar origins in the deep interior of Mars but that the surface rocks come from a more oxygen-rich environment, probably caused by recycling of oxygen-rich materials into the interior. This result is surprising because while the meteorites are geologically young, around 180 million to 1.4 billion years old, the Spirit rover was analyzing a very old part of Mars, more than 3.7 billion years old.
In addition to evidence that Mars once had a sizable amount of surface water, in the form of rivers and lakes, this latest study demonstrates that Mars was once very much like Earth. In all likelihood, it would have been home to countless forms of bacteria, single-celled organisms, and possibly larger creatures as well. But being at the edge of our Sun’s habitable zone, it was unable to maintain the conditions for life to thrive.
Sad news, but encouraging when it comes to the prospect of making Mars able to sustain life again. And in the coming years and decades, that’s precisely what a number of space agencies, private companies and citizens want to do. And if these plans are to succeed long term, the planet will have to be converted into something that can independently support life.
In short, the colonization of Mars requires that the planet become something akin to its old self.
It seems that a new field of study was threatening to emerge with the “discovery” of what appeared to be a Martian rat. The technical term for it is Martian mammology, the study of mammals that are native to Mars. Luckily, proponents of this field did not manage to overpower the good people at NASA, who remain dedicated to serious scientific research. And now, the Curiosity rover is moving on to study bigger and better things.
Yes, the appearance of this would-be rodent did generate a lot of buzz on the internet of late, with some UFO buffs claiming that it may be an indigenous Red Planet lifeform or an Earth rodent Curiosity carried to Mars as part of a secret experiment. But Curiosity scientists were relatively certain that the rat, which was spotted in a zoomed-in portion of a photo taken by the rover in September 2012, was just a rock.
Curiosity deputy project scientist Joy Crisp, of NASA’s Jet Propulsion Laboratory in Pasadena, Calif., told reporters on Wednesday, June 5, what they believed the curiously-shaped rock was the result of:
Clearly, it results from, you know, a lot of things like wind erosion and mechanical abrasion and breakdown chemical weathering of the rocks, as to why they get these weird shapes.
Under the circumstances, NASA does not feel the need to conduct any further studies. And the window to do so will last just a few more weeks, as the Curiosity rover is set to begin an epic drive that will take it far away from the petrified rodent. At the moment, the robot is gearing up for a year-long trek that will take it to the base of Mount Sharp, a mysterious mountain that rises 5.5 km (3.4 miles) into the Red Planet sky.
Curiously (no pun!), this is not the first time people have seen faced in the rock surfaces of Mars. Remember the elusive “Face on Mars”? Originally taken by the Viking 1 spacecraft in 1976, this low-resolution picture of the Cydonia region of Mars ignited the imaginations of people all over the world. For years, the face was mentioned in feature films, television series’, video games, comics, and even pop music.
Even after a series of high-resolution photos – taken some twenty years later by a succession of space craft – proved it to just be a simple rock formation, many people still insisted that the “face” was real and proved the existence of intelligent life on Mars. And such examples are hardly reserved to the Red Planet. Every year, there are stories of people witnessing “miracles” as divine visions appear to them in seemingly random objects, either of religious figures or personal heroes.
It’s whats known as pareidolia, a psychological phenomenon which refers to the human brain’s tendency to spot familiar things in random images. According to Crisp, this is not necessarily a bad thing. In truth, she claims NASA scientists get amused when this happens:
It’s fun in a way, too, in that it will attract a lot of the public to look at the images and learn a little bit about Mars by pulling them in this way.
So much like people seeing the Virgin Mary in a wall-stain, Mother Teresa in a cinnamon bun, or the face of Jesus and/or Elvis in their grilled cheese sandwich, the Mars Rat is likely to be with us for awhile yet. Perhaps he’ll go beyond the current internet meme and start a trend, with t-shirts and apparel for all. All he needs is a slogan: “Mars Rat Says ‘That’s My Cheese!'” …I’ll work on it 😉
As the projected date for a manned mission to the Red Planet approaches, the Mars Science Laboratory and Curiosity team continue to conduct vital research into what a human team of explorers can expect to find. Unfortunately, earlier last month, that research led to a discouraging announcement which may force NASA and a number of private companies to rethink their plans for manned missions.
Earlier in May, a number of scientists, NASA officials, private space company representatives and other members of the spaceflight community gathered in Washington D.C. for a three day meeting known as the Humans to Mars (H2M) conference. Hosted by the spaceflight advocacy group Explore Mars, the attendees met to discuss all the challenges that a 2030 manned mission would likely encounter.
For starters, the human race currently lacks the technology to get people to Mars and back. An interplanetary mission of that scale would likely be one of the most expensive and difficult engineering challenges of the 21st century. Currently, we don’t have the means to properly store enough fuel to make the trip, or a vehicle capable of landing people on the Martian surface. Last, and most importantly, we aren’t entirely sure that a ship will keep the astronauts alive long enough to get there.
This last issue was raised thanks to a recent confirmation made by the Curiosity rover, which finished calculating the number of high-energy particles that struck it during its eight month journey to Mars. Based on this data, NASA says that a human traveling to and from Mars could well be exposed to a radiation dose that is beyond current safety limits.
This was performed with the rover’s Radiation Assessment Detector (RAD) instrument, which switched on inside as the cruise vessel began its 253-day, 560-million-km journey. The particles of concern fall into two categories – those that are accelerated away from our Sun and galactic cosmic rays (GCRs) – those that arrive at high velocity from outside of the Solar System. This latter category is especially dangerous since they impart a lot of energy when they strike the human body, can cause damage to DNA and are hard to shield against.
What’s more, this calculation does not even include time spent on the planet’s surface. Although Curiosity has already determined that planetary levels were within human tolerances, the combined dosage would surely lead to a fatal case of cancer for any career astronaut looking to take part in an “Ares Mission”. Cary Zeitlin from the Southwest Research Institute in Boulder, Colorado, and colleagues reported the Curiosity findings in the latest edition of Science magazine.
They claim that engineers will have to give careful consideration to the type of shielding that will need to be built into a Mars-bound crew ship. However, they concede that for some of the most damaging radiation particles, there may be little that can be done, beyond delivering them to Mars as quickly as possible. This presents an even greater challenge, which calls for the development of something better than existing propulsion technology. Using chemical propellants, Curiosity made the trip in eight months.
However, the good news is that at this juncture, nothing is technologically impossible about a manned Mars mission. It’s just a matter of determining what the priorities are and putting the time and money into developing the necessary tools. Right now NASA, other space agencies, and private companies are working to bring Mars within reach. And with time and further developments, who knows what will be possible by the time the 2020’s roll around?
Some alternatives include plasma and nuclear thermal rockets, which are in development and could bring the journey time down to a number of weeks. What’s more, SpaceX and other agencies are working on cheaper deliver systems, such as the grasshopper reusable rocket, to make sending ships into space that much more affordable. In addition, concepts for improving radiation shielding – like Inspiration Mars’ idea of using human waste – are being considered to cut down on the irradiation factor.
So despite the concerns, it seems that we are still on track for a Mars mission in 2030. And even if there are delays in the implementation, it seems as though a manned mission is just a matter of time at this point. Red Planet, here we come!
Throughout the summer, six people participated in an experiment designed to test how people will deal with the physical and psychological strangeness of a manned space journey. Known as the “Hawaii Space Exploration Analog and Simulation” (HI-SEAS) study, the research took place on a desolate slope of an abandoned quarry in Hawaii, 8,000 feet above sea level.
For years now, scientists have been trying to find ways to make astronaut food more palatable. In space, the food is either dehydrated and requires water and heat to process, or is rendered in liquid form that has to be drunk right out of the package. But on Mars, where there would be gravity, astronauts could actually cook their own food from “shelf-stable” ingredients.
As Greene indicated, she came to miss such things as walking about outside, biking, and swimming, and gained a new appreciation for her old life:
All of this information is likely to be very useful in coming years and decades. Back in August, on the one-year anniversary of the Curiosity Rover’s landing on Mars, NASA chief Charles Bolden said he believed that human footprints would follow in its path, and 2030 remains the projected date for putting those boots on the Red Planet.
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