Atlas Rocket Launches AMC-10 Satellite

Image credit: ILS
International Launch Services (ILS) scored another success tonight, with the launch of the AMC-10 satellite on board a Lockheed Martin-built Atlas IIAS rocket.

The rocket lifted off at 6:46 p.m. from Cape Canaveral?s Space Launch Complex 36A, and placed the satellite into a transfer orbit 28 minutes later. The satellite is an A2100 model, built by Lockheed Martin for SES AMERICOM of Princeton, N.J. This was the first launch of the year for ILS. It also is one of four missions for SES AMERICOM on the ILS manifest this year.

?We are gratified and honored that such a prominent satellite operator as SES AMERICOM has signaled such confidence in our team,? said ILS President Mark Albrecht. ?Since the AMC-10 and AMC-11 satellites are two of a kind, we fully expect to be repeating another successful mission right here at the Cape in a few months? time.?

Albrecht noted the long-standing relationship with ILS and SES AMERICOM, and its parent company, SES GLOBAL. To date ILS has launched 15 satellites for companies affiliated with SES GLOBAL, including six for the SES AMERICOM fleet. ?With the SES family as the world?s largest satellite operator, it is no secret that we relish the fact that ILS is its largest launch services provider. We?re pleased to be welcoming them back again this year to both our launch sites ? at the Cape and in Kazakhstan ? for SES AMERICOM missions this year,? Albrecht said. Two SES AMERICOM satellites ? AMC-12 and AMC-15 ? are set to launch on Proton vehicles in 2004.

ILS is a joint venture of Lockheed Martin (NYSE:LMT) and Russian rocket builder Khrunichev State Research and Production Space Center. ILS markets and manages the missions on the Atlas rocket in the United States and on the Proton rocket at the Baikonur Cosmodrome, Kazakhstan. ILS was formed in 1995, and is based in McLean, Va., a suburb of Washington, D.C.

Dean Olmstead, president and CEO of SES AMERICOM, said: “The AMC-10 mission enables us to continue delivering the highest quality distribution services to the top-tier cable programmers who entrust us with more channels and their new high-definition services; in turn we have entrusted this satellite to ILS and its terrifically reliable Atlas IIAS launch vehicle. Our hope is that the AMC-11 launch planned for May will proceed just as flawlessly as tonight’s AMC-10 launch.”

Tonight?s rocket was the 27th flown in the Atlas IIAS configuration. Three more Atlas IIAS vehicles are scheduled to launch this year before the model is retired. ILS also has customers scheduled on Atlas III and Atlas V vehicles this year. The Atlas II, III and V series have achieved 100 percent success through 69 consecutive launches. The Atlas IIAS can lift 8,200 pounds to geosynchronous transfer orbit. The Atlas III can lift up to 9,920 pounds, and the current -production Atlas V is available in a range of configurations to lift payloads up to 19,000 pounds.

The Atlas rockets and their Centaur upper stages are built by Lockheed Martin Space Systems Company in Denver, Colo.; Harlingen, Texas; and San Diego, Calif. The A2100 satellite is built by Lockheed Martin Commercial Space Systems in New Town, Pa., and Sunnyvale, Calif.

Original Source: ILS News Release

I’m Looking for Experts to Answer Reader Questions

We get a lot of space and astronomy questions on the Universe Today forum, and we answer what we can. Many times, though, the question is more detailed and technical and really requires an expert to answer. I’ve got a list of astronomers and scientists that I sometimes turn to, but I could always use more.

If you’re working in space and astronomy, and willing to answer the occasional reader question, please drop me an email. I would really appreciate it. It probably wouldn’t be more than a question every few months, so nothing too onerous.

Oh? and keep asking your questions, we’ll keep looking for the answers.

Thanks!

Fraser Cain
Publisher
Universe Today

More Support for Life in Martian Meteorite

Image credit: NASA
University of Queensland researchers have confirmed the theory life once existed on Mars.

Dr John Barry, from UQ?s Centre for Microscopy and Microanalysis, together with former UQ researcher Dr Tony Taylor, found their proof in the water trap at the ninth hole of the Howestern golf course at Birkdale.

Mud samples from the golf course contained magnetic crystals which matched those found in a meteorite discovered in Antartica in 1984.

In 1996 NASA announced it had found primitive bacteria in that meteorite and since then debate has raged in the scientific community whether the organism were from Mars.

Dr Taylor, together with his PhD co-supervisor Dr Barry, examined the mud samples using a world-first breakthrough in electron microscopy and found the fossil bacteria and the new samples were identical.

?Tony developed a new technique to capture specimens for the electron microscope which allowed us to see through the bacteria and into the gel surrounding the magnetic crystals inside the bacterium,? Dr Barry said.

?This gave us a lot more information about the structure than what we would have seen before.?

Dr Taylor, who now works for the Australian Nuclear Science and Technology Organisation in Sydney, said this research seriously challenges doubts of sceptical scientists by discovering that many bacteria match the features found in the Martian meteorite.

?Our research shows that the structures found in the NASA meteorite were more than likely made by bacteria present on Mars four billion years ago, before life even started on Earth,? said Dr Taylor.

Dr Taylor said the discovery was the product of painstaking research conducted with other scientists in the 1990s that vastly improved imaging techniques to study bacterial structures. Ultraviolet light was the key and resulted in the detailed analysis of 82 different bacterial types – a major improvement on the 25 identified at that time.

?We became very excited when we discovered that many of the bacteria found had the same biosignature, which resembles a tiny backbone surrounded by cartilage, as that of the Martian fossils,? Dr Taylor said.

Emeritus Professor Imre Friedmann, one of the original NASA scientists to make the life on Mars claim said he was thrilled by the news.

?The Study of Taylor and Barry now presents evidence that the same features occur in a wide range of bacteria that live on Earth today. The tiny structures, chains of crystals of the mineral magnetite, are comparable to animal skeletons on a microscopic scale, ? Professor Friedmann said.

Dr Barry and Dr Taylor?s research was published recently in the Journal of Microscopy.

Original Source: University of Queensland News Release

Rosetta Lander Named Philae

Image credit: ESA
With just 21 days to the launch of the European Space Agency’s Rosetta comet mission, the spacecraft’s lander has been named “Philae”. Rosetta embarks on a 10-year journey to Comet 67P/Churyumov-Gerasimenko from Kourou, French Guiana, on 26 February.

Philae is the island in the river Nile on which an obelisk was found that had a bilingual inscription including the names of Cleopatra and Ptolemy in Egyptian hieroglyphs. This provided the French historian Jean-Fran?ois Champollion with the final clues that enabled him to decipher the hieroglyphs of the Rosetta Stone and unlock the secrets of the civilisation of ancient Egypt.

Just as the Philae Obelisk and the Rosetta Stone provided the keys to an ancient civilisation, the Philae lander and the Rosetta orbiter aim to unlock the mysteries of the oldest building blocks of our Solar System – comets.

Germany, France, Italy and Hungary are the main contributors to the lander, working together with Austria, Finland, Ireland and the UK. The main contributors held national competitions to select the most appropriate name. Philae was proposed by 15-year-old Serena Olga Vismara from Arluno near Milan, Italy. Her hobbies are reading and surfing the internet, where she got the idea of naming the lander Philae. Her prize will be a visit to Kourou to attend the Rosetta launch.

Study of Comet Churyumov-Gerasimenko will allow scientists to look back 4600 million years to an epoch when no planets existed and only a vast swarm of asteroids and comets surrounded the Sun. On arrival at the comet in 2014, Philae will be commanded to self-eject from the orbiter and unfold its three legs, ready for a gentle touchdown. Immediately after touchdown, a harpoon will be fired to anchor Philae to the ground and prevent it escaping from the comet’s extremely weak gravity. The legs can rotate, lift or tilt to return Philae to an upright position.

Philae will determine the physical properties of the comet’s surface and subsurface and their chemical, mineralogical and isotopic composition. This will complement the orbiter’s studies of the overall characterisation of the comet’s dynamic properties and surface morphology. Philae may provide the final clues enabling the Rosetta mission to unlock the secrets of how life began on Earth.

?Whilst Rosetta?s lander now has a name of its own, it is still only a part of the overall Rosetta mission. Let us look forward to seeing the Philae lander, Osiris, Midas and all the other instruments on board Rosetta start off on their great journey this month,? said Professor David Southwood, ESA Director of Science.

Original Source: ESA News Release

Rover Sees Spheres in the Martian Soil

Image credit: NASA/JPL
NASA’s Opportunity has examined its first patch of soil in the small crater where the rover landed on Mars and found strikingly spherical pebbles among the mix of particles there.

“There are features in this soil unlike anything ever seen on Mars before,” said Dr. Steve Squyres of Cornell University, Ithaca, N.Y., principal investigator for the science instruments on the two Mars Exploration Rovers.

For better understanding of the soil, mission controllers at NASA’s Jet Propulsion Laboratory, Pasadena, Calif., plan to use Opportunity’s wheels later this week to scoop a trench to expose deeper material. One front wheel will rotate to dig the hole while the other five wheels hold still.

The spherical particles appear in new pictures from Opportunity’s microscopic imager, the last of 20 cameras to be used on the two rover missions. Other particles in the image have jagged shapes. “The variety of shapes and colors indicates we’re having particles brought in from a variety of sources,” said Dr. Ken Herkenhoff of the U.S. Geological Survey’s Astrogeology Team, Flagstaff, Ariz.

The shapes by themselves don’t reveal the particles’ origin with certainty. “A number of straightforward geological processes can yield round shapes,” said Dr. Hap McSween, a rover science team member from the University of Tennessee, Knoxville. They include accretion under water, but apparent pores in the particles make alternative possibilities of meteor impacts or volcanic eruptions more likely origins, he said.

A new mineral map of Opportunity’s surroundings, the first ever done from the surface of another planet, shows that concentrations of coarse-grained hematite vary in different parts of the crater. The soil patch in the new microscopic images is in an area low in hematite. The map shows higher hematite concentrations inside the crater in a layer above an outcrop of bedrock and on the slope just under the outcrop.

Hematite usually forms in association with liquid water, so it holds special interest for the scientists trying to determine whether the rover landing sites ever had watery environments possibly suitable for sustaining life. The map uses data from Opportunity’s miniature thermal emission spectrometer, which identifies rock types from a distance.

“We’re seeing little bits and pieces of this mystery, but we haven’t pieced all the clues together yet,” Squyres said.

Opportunity’s Moessbauer spectrometer, an instrument on the rover’s robotic arm designed to identify the types of iron- bearing minerals in a target, found a strong signal in the soil patch for olivine. Olivine is a common ingredient in volcanic rocks. A few days of analysis may be needed to discern whether any fainter signals are from hematite, said Dr. Franz Renz, science team member from the University of Mainz, Germany.

To get a better look at the hematite closer to the outcrop, Opportunity will go there. It will begin by driving about 3 meters (10 feet) tomorrow, taking it about halfway to the outcrop. On Friday it will dig a trench with one of its front wheels, said JPL’s Dr. Mark Adler, mission manager.

Opportunity’s twin, Spirit, today is reformatting its flash memory, a preventive measure that had been planned for earlier in the week. “We spent the last four days in the testbed testing this,” Adler said. “It’s not an operation we do lightly. We’ve got to be sure it works right.” Tomorrow, Spirit will resume examining a rock called Adirondack after a two-week interruption by computer memory problems. Controllers plan to tell Spirit to brush dust off of a rock and examine the cleaned surface tomorrow.

Each martian day, or “sol,” lasts about 40 minutes longer than an Earth day. Spirit begins its 33rd sol on Mars at 2:43 a.m. Thursday, Pacific Standard Time. Opportunity begins its 13th sol on Mars at 3:04 p.m. Thursday, PST.

JPL, a division of the California Institute of Technology in Pasadena, manages the Mars Exploration Rover project for NASA’s Office of Space Science, Washington, D.C. Images and additional information about the project are available from JPL at http://marsrovers.jpl.nasa.gov and from Cornell University at http://athena.cornell.edu.

Original Source: NASA/JPL News Release

Wallpaper: Hubble’s View of M64

Image credit: Hubble
A collision of two galaxies has left a merged star system with an unusual appearance as well as bizarre internal motions. Messier 64 (M64) has a spectacular dark band of absorbing dust in front of the galaxy’s bright nucleus, giving rise to its nicknames of the “Black Eye” or “Evil Eye” galaxy.

Fine details of the dark band are revealed in this image of the central portion of M64 obtained with the Hubble Space Telescope. M64 is well known among amateur astronomers because of its appearance in small telescopes. It was first cataloged in the 18th century by the French astronomer Messier. Located in the northern constellation Coma Berenices, M64 resides roughly 17 million light-years from Earth.

At first glance, M64 appears to be a fairly normal pinwheel-shaped spiral galaxy. As in the majority of galaxies, all of the stars in M64 are rotating in the same direction, clockwise as seen in the Hubble image. However, detailed studies in the 1990’s led to the remarkable discovery that the interstellar gas in the outer regions of M64 rotates in the opposite direction from the gas and stars in the inner regions.

Active formation of new stars is occurring in the shear region where the oppositely rotating gases collide, are compressed, and contract. Particularly noticeable in the image are hot, blue young stars that have just formed, along with pink clouds of glowing hydrogen gas that fluoresce when exposed to ultraviolet light from newly formed stars.

Astronomers believe that the oppositely rotating gas arose when M64 absorbed a satellite galaxy that collided with it, perhaps more than one billion years ago. This small galaxy has now been almost completely destroyed, but signs of the collision persist in the backward motion of gas at the outer edge of M64.

This image of M64 was taken with Hubble’s Wide Field Planetary Camera 2 (WFPC2). The color image is a composite prepared by the Hubble Heritage Team from pictures taken through four different color filters. These filters isolate blue and near-infrared light, along with red light emitted by hydrogen atoms and green light from Str?mgren y.

Original Source: Hubble News Release

Nearby Galaxy is Hotbed of Star Formation

Image credit: Hubble
The nearby dwarf galaxy NGC 1569 is a hotbed of vigorous star birth activity which blows huge bubbles that riddle the main body of the galaxy. The galaxy’s “star factories” are also manufacturing brilliant blue star clusters. This galaxy had a sudden onset of star birth about 25 million years ago, which subsided about the time the very earliest human ancestors appeared on Earth.

In this new image, taken with NASA’s Hubble Space Telescope, the bubble structure is sculpted by the galactic super-winds and outflows caused by a colossal input of energy from collective supernova explosions that are linked with a massive episode of star birth.

One of the still unresolved mysteries in astronomy is how and when galaxies formed and how they evolved. Most of today’s galaxies seem to have been already fully formed very early on in the history of the universe (now corresponding to a large distance away from us), their formation involving one or more galaxy collisions and/or episodes of strongly enhanced star formation activity (so-called starbursts).

While any galaxies that are actually forming are too far away for detailed studies of their stellar populations even with Hubble, their local counterparts, nearby starburst and colliding galaxies, are far easier targets.

NGC 1569 is a particularly suitable example, being one of the closest starburst galaxies. It harbors two very prominent young, massive clusters plus a large number of smaller star clusters. The two young massive clusters match the globular star clusters we find in our own Milky Way galaxy, while the smaller ones are comparable with the less massive open clusters around us.

NGC 1569 was recently investigated in great detail by a group of European astronomers who published their results in the January 1, 2004 issue of the British journal, Monthly Notices of the Royal Astronomical Society. The group used several of Hubble’s high-resolution instruments, with deep observations spanning a wide wavelength range, to determine the parameters of the clusters more precisely than is currently possible from the ground.

The team found that the majority of clusters in NGC 1569 seem to have been produced in an energetic starburst that started around 25 million years ago and lasted for about 20 million years. First author Peter Anders from the Gottingen University Galaxy Evolution Group, Germany says “We are looking straight into the very creation processes of the stars and star clusters in this galaxy. The clusters themselves present us with a fossil record of NGC 1569’s intense star formation history.”

The bubble-like structures seen in this image are made of hydrogen gas that glows when hit by the fierce winds and radiation from hot young stars and is racked by supernovae shocks. The first supernovae blew up when the most massive stars reached the end of their lifetimes roughly 20-25 million years ago. The environment in NGC 1569 is still turbulent and the supernovae may not only deliver the gaseous raw material needed for the formation of further stars and star clusters, but also actually trigger their birth in the tortured swirls of gas.

The color image is composed of 4 different exposures with Hubble’s Wide Field and Planetary Camera 2 through the following filters: a wide ultraviolet filter (shown in blue), a green filter (shown in green), a wide red filter (shown in red), and a Hydrogen alpha filter (also shown in red).

Original Source: Hubble News Release

Is NASA Following in the Footsteps of the X-Prize?

NASA has released its fiscal year 2005 budget, which includes specific prizes for the various activities outlined in President Bush’s new space initiative announced earlier in January. One interesting line item is $20 million set aside for something called the “Centennial Challenges“. Here’s the description:

Request includes funding to establish a series of annual prizes for revolutionary, breakthrough accomplishments that advance exploration of the solar system and beyond and other NASA goals. Some of the most difficult technical challenges to exploration will require very novel solutions from non-traditional sources of innovation. By making awards based on actual achievements instead of proposals, NASA will tap innovators in academia, industry, and the public who do not normally work on NASA issues. Centennial Challenges will be modeled on past successes, including 19th century navigation prizes, early 20th century aviation prizes, and more recent prizes offered by the U.S. government and private sector. Examples of potential Centennial Challenges include very-low-cost space missions, contests to demonstrate highly mobile, capable, and survivable robotic systems, and fundamental advances in technical areas like lander navigation, spacecraft power systems, life detection sensors, and nano-materials.

This sounds like NASA is going to be awarding prizes for successful space accomplishments, similar to the privately-funded $10 million X-Prize that will reward the first private firm to achieve sub-orbital flight twice within two weeks. Prizes like this have been one of the most successful technology drivers in the past; one of the best known examples is the Orteig Prize, won by Charles Lindbergh, which demonstrated that flights across the Atlantic Ocean were possible.

Pretty exciting news, we’ll see how this turns out.

Fraser Cain
Publisher
Universe Today

P.S. Thanks to Spaceprojects.com for the heads up.

Can the Rovers Find Life on Mars?

Image credit: ESA
Astrobiology Magazine (AM): The first batch of images from Meridiani Planum, showing finely layered bedrock, have scientists pretty excited. What are your initial impressions?

Andrew Knoll (AK): We’ve known for several years, from orbital data, that there are layered rocks on Mars, but Opportunity gives us our first chance to actually go and work directly on some of these rocks in an outcrop. For geologists, you just can’t overemphasize the importance of that.

The fact that they’re sort of tabular suggests that they’re either fairly thin volcanic deposits or sediments. And the prospect of having in situ sedimentary rocks on Mars that we can go up and interrogate is about a best-case scenario, as far as I’m concerned.

AM: What if they turn out to be volcanic ash deposits? Will that make for a less interesting scenario?

AK: Not at all. I think one of the big questions is, What are the predominant processes that have given rise to layered rocks on Mars? There’s no reason to believe that every layered rock on Mars formed in the same way as the ones that Opportunity’s sitting in front of. But to know even how one of those layered rocks formed will be a step in the right direction.

We will also soon know whether the hematite signal in Meridiani that was detected from orbit is resident in those rocks. Remember the reason that we’re at Meridiani Planum is because of this strong signal for a particular form of iron oxide called hematite. It’s very difficult to think about making hematite without some liquid water interactions with rocks. So even if it’s a volcanic rock, it will help to constrain our thinking about one of the most interesting chemical anomalies on the planet.

AM: There’s a river in Spain, the Rio Tinto, where you’ve spent some time doing research. You’ve suggested that the way the iron minerals at Rio Tinto have degraded and transformed over time might shed some light on how the hematite at Meridiani formed. Can you explain the connection?

AK: Let me start at the beginning. The kinds of thinking we bring to the interpretation of iron on Mars will be informed by our experience with oxidized iron on the Earth’s surface. There are a number of ways that iron deposits have formed on our planet. It may be that no one of them is going to be an exact analog for what happened on Mars. But each of them might give tidbits of information that will help us think about Mars.

Now, Rio Tinto is a very interesting place. It’s in southwestern Spain, about an hour west of Seville, maybe another hour east of the Portuguese border. Rio Tinto is actually of historical interest to people in America since Columbus set sail in 1492 from a port at the mouth of the Rio Tinto. But it’s also of interest to mining geologists because it has been a mine at least since the time of the Romans.

What’s being mined there is iron ore. About 400 million years ago hydrothermal processes formed these iron ore deposits. Mostly the iron is in the form of iron sulfide, or fool’s gold. It’s very rich ore. As rainwater percolates down through these deposits, it oxidizes the pyrite and two things happen. One, it forms sulfuric acid. So the water in the river has a pH of about 1; it’s very acidic. And, two, the iron gets oxidized. So the water is about the color of rubies, because of this iron being carried around.

What’s interesting is that if you look at the deposits that are forming from the Rio Tinto today, most of the iron is coming out as iron sulfate minerals, that is, a combination of iron, sulfur and oxygen; and a little bit of it is coming out as a mineral called goethite, which is iron mixed with oxygen and a little bit of hydrogen. Goethite is basically rust.

That’s not what you see at Meridiani on Mars. But what’s interesting about the Rio Tinto deposit is that this process has been taking place for at least 2 million years. And there is a series of terraces that give us a sense of what happens to these deposits over time.

What we find is that after just a few thousand years, all of the sulfate minerals have disappeared and all of the iron is in this material called goethite. But as you go into older and older terraces, by the time you get to terraces that are 2 million years old, much of that goethite has been replaced by hematite, the mineral on Mars. And it’s a fairly coarse-grained hematite, which is also what we see at Mars.

So the first thing we learn at Rio Tinto is that one doesn’t need to think only about processes that deposit coarse-grained hematite from the get-go. It can form during what geologists call diagenesis. That is, it can form by processes that affect the rocks through time, and it can actually do that at low temperatures and without being deeply buried and subjected to high pressure. So in that sense, Rio Tinto shows us another way in which the hematite in Meridiani could have gotten there. It expands the options we consider.

AM: When geologists say things like “low temperature,” they often mean something different than the rest of us do.

AK: When I say “low temperature,” I’m talking about the temperatures that you and I experience on a daily basis, room temperature. I would guess that most of the Rio Tinto groundwaters are between 20 and 30 degrees Celsius, maybe 70 to 80 degrees Farenheit.

AM: Does the texture of the rock change over time as a mineral goes through the process of diagenesis?

AK: Yes, it does. Although what’s interesting is that while texture at the level of what the microscopic imager can see definitely changes through diagenetic history, larger scale features of deposition that you would see by looking closely at the outcrop with Pancam appear to be persistent. So, even though the rock is going through these changes, it retains sedimentary signatures of its formation, which is exciting. That’s important.

AB: You say that at Rio Tinto you can see a 2-million-year slice that shows you the diagenetic process over time. But the outcrops that Opportunity has seen at Meridiani could be 2 billion years old. Would they still retain any useful information after that long?

AK: Here’s the good news about geology: For sedimentary rocks, in particular, most of the changes that a rock undergoes it undergoes very early in its history. Unless a rock undergoes metamorphism, getting buried and subjected to high pressures and temperature, within at most a few million years of its formation it stabilizes into a form that it will retain indefinitely.

I work, in my day job, on Precambrian rocks on this planet. And I can guarantee you that when I look at a sedimentary rock that’s a billion years old, most of the changes that that rock underwent happened within the first 200 thousand years of its life. And then it stabilizes, and just waits for a geologist.

AM: And we have no reason to believe that physics behaves differently on Mars?

AK: That’s what we have going for us. I’ve said this before in terms of astrobiology: When you’re looking for life beyond our planet, you have no assurance that biology somewhere else will be the same as it is here. But you have pretty good assurance that physics and chemistry will be the same.

AM: Part of what makes Meridiani interesting is that it’s unlike just about any place else on Mars. Even if you’re able to figure out the history of Meridiani, to what extent will you be able to generalize that knowledge to Mars as a whole?

AK: I think it will certainly constrain the way we think about Mars as a whole planet. It may be that, in terms of the overall chemical and rock signature of Mars, that Gusev will turn out to be a better standard-issue Mars surface. That is, most of Mars – in fact, almost all of Mars – is surfaced with basalt, and then covered with fine dust. And that’s what we see at Gusev.

Now, it turns out that if you strip away the signal of hematite from the signatures of surface materials in Meridiani that we’ve gotten from orbit, it’s also mainly basalt. So it’s not a completely anomalous part of the planet. It appears to be a representative part of the planet at heart, with this unique hematite signal layered onto it.

One of the features of the Meridiani iron deposit is that, while it’s local with respect to the whole planet, it’s geographically widespread in that you have thousands of square kilometers that give this signature.

Many people think that hydrothermal processes and groundwater processes will give only small local iron signals, but in fact, the hematite-rich layers in the Rio Tinto deposit, go for several thousand square kilometers. Because these groundwaters spread out in a layer over a wide area.

So the Rio Tinto iron deposits do several things that we should keep in mind at Meridiani. They combine ancient hydrothermal and younger low-temperature processes; they need water; they can be layer forming; and they can be widespread.

They’re not the only set of processes that could to that, by any means. I’m not particularly prejudiced in favor of Rio Tinto as a better analog to Meridiani than anything else. I just think that as we go into this exploration we need to at least keep in our memory file as many different products and processes dealing with iron as we can.

All of the different settings for iron deposition and processes of iron deposition we see on this planet carry chemical and textural signals that Opportunity could detect on Meridiani. We can use those comparisons to help us to figure out how the Meridiani hematite formed.

AM: One of the intriguing aspects of Rio Tinto as a research site is that even though the water in the river is highly acidic, there are bacteria living in it. When you look at the ancient hematite deposits in that region, do you see fossil bacteria?

AK: Yes, you do. In fact, one of the things that attracted me to work with my Spanish colleagues was not that it’s an oddball environment today. While it’s kind of fun to be interested in life on the environmental fringes today, most life – and much of what you can learn about biology today – comes from ordinary organisms living in ordinary circumstances. That’s where 99 percent of the diversity of life is.

On the other hand, there’s a great question that can be asked at Rio Tinto. We can see the processes that formed the Rio Tinto iron deposits going on today; we can see the chemical processes; we can see what biology is in the environment. But the real question that one wants to keep in mind when thinking about Meridiani is: What, if any, signatures of that biology actually get preserved in diagenetically stable rocks?

One is that. If you were lucky enough to have access to a microscope – this would probably be at a resolution beyond what you could hope for from the microscopic imager – you could see individual microbial filaments that have been beautifully preserved. So that’s the first good news is that diagenetically stabilized iron can retain a microscopic imprint of biology.

The better news is that there are two features of biology that get preserved in the more eyeball-level textures in these rocks.

One is that you sometimes get little bubbles forming because of gas emanation from metabolism. And some of those will actually roof over with iron minerals and can be preserved through diagenesis. And that’s pretty much true through most sedimentary rocks that we find in the geologic column. You can get preserved gas spaces and those gas spaces are invariably associated with biological production of gases.

AM: How invariably?

AK: In our experience on Earth, it’s pretty much 100 percent. What you’d want to ask is: What processes other than biology might give rise to gases within a sediment on a planet? That’s something that you can do experiments on. I don’t know that anyone’s bothered to do them on this planet. Because, frankly, biology is so pervasive that that’s the main game in town, anyway. But one could do the experiments.

The other thing, which I feel even more strongly about, is that many times, where there are microbial populations, they form these beautiful groups of filaments that just string out across the surface. They almost look like the mane of a horse. Now the great thing is that, when minerals are deposited in these environments, they actually nucleate on these strings of filaments, and you get beautiful sedimentary textures that, again, look like the mane of a horse.

You can see them in Yellowstone Park, in both siliceous and carbonate-precipitating strings. If you go to places like Mammoth Springs, you can see it happening today. And if you hike into the hinterland, you can see ancient examples of that, beautiful signatures preserved in the rock.

In Rio Tinto, you can see iron depositing on these filaments; and in the 2 million year old terraces, you can see these filamentous iron textures. And there, again, I know of no process other than biology that could form those. So that’s truly something to keep your eyes out for whenever you’re looking at a precipitated rock on Mars.

AM: And you could see these with Pancam?

AK: If you took a Pancam to Rio Tinto or Yellowstone Park, they would jump out at you. Absolutely.

AM: If it turns out that the bedrock at the Opportunity landing site is made up of sedimentary deposits, does that mean that when those sediments were laid down, there had to be liquid water around?

AK: Very likely.

AM: So if they were sedimentary, and Pancam saw some sort of texture that on Earth is indicative of biology, would that mean that Opportunity had come close to finding evidence of life on Mars?

AK: Those are big ifs, but it would be a big day.

Let’s back up a second, because it gets to a little bit of philosophy about how you actually look for these things. A couple of years ago, NASA embarked on a funding campaign to essentially try and anticipate any kind of suggestively biological signature that might be found in any kind of exploration of another planet so that we wouldn’t be seen to be scratching our heads.

But the plain fact is that you can’t anticipate anything you might see. So what I think is a more realistic scenario is that you do your exploration, and if, in the course of that exploration, you find a signal that is (a) not easily accounted for by physics and chemistry or (b) reminiscent of signals that are closely associated with biology on Earth, then you get excited.

What will happen then, I can guarantee you, is that 100 enterprising scientists will go into the lab and see how, if at all, they can simulate what you see – without using biology. And I think that’s the right thing to do. For things where the stakes are so high, I think one wants to be as careful and sober about this as you can be. And certainly that means knowing a lot more about the generative capacity of physical and chemical processes to implant both chemical and textural signatures in a rock than we know about today.

Absent astrobiology, nobody would waste their time doing these things because, on Earth, we know that there has been biology for most of the planet’s history. Biology is everywhere. Biology is pre-eminent in the signals that it imparts to sedimentary rocks. So who is going to spend five years of their time as a young scientist trying to generate a signal by abiological means that’s closely associated with biology? However, you switch to Mars and there are a lot more reasons to do that kind of thing.

AM: If one of the MER rovers found a rock that seemed to contain evidence of martian biology, would NASA want go back to that spot and bring it home?

AK: You bet. Depending on what we find in Meridiani – not to prejudice what we find – it may make it either a very high-priority site for NASA to return with more sophisticated equipment and be a very top priority site for sample return; or we may write it off.

That’s the whole reason for this sort of incremental work. I actually like the whole architecture of NASA’s plan to go one step at a time, do each step carefully, and in step two build on what you learned in step one. It makes sense.

AM: I realize I’m asking you to speculate, here, but what do you think are the odds that Mars was once a living world?

AK: I really don’t know. But everything we’ve learned in the last few years suggests to me that water may have been episodic rather than persistent on Mars. And that lowers the probability for biology.

If water is present on the Martian surface for 100 years every 10 million years, that’s not very interesting for biology. If it’s present for 10 million years, that’s very interesting.

It is certainly not a given that we will find that Mars was a biological planet. Half of my brain keeps trying to throw out a percentage, and I know it’s such a meaningless thing to do – I think I’m just going to not do it.

But I can tell you that one of the best chances we’re going to get for a number of years to address that question is right here in the iron deposits of Meridiani.

Original Source: Astrobiology Magazine

Closeup Look at Martian Soil

Image credit: NASA/JPL
This magnified look at the martian soil near the Mars Exploration Rover Opportunity’s landing site, Meridiani Planum, shows coarse grains sprinkled over a fine layer of sand. The image was captured by the rover’s microscopic imager on the 10th day, or sol, of its mission and roughly approximates the color a human eye would see. Scientists are intrigued by the perfectly round pebbles, which most likely were formed by one of two geologic processes. The first, accretion, is the same mechanism by which pearls take shape in oysters: concentric layers of material build up around a “seed.” The seed, in this case, may be either waterborne particles or volcanic ash. In the second process, droplets of material are sprayed into the air, by either volcanic eruptions or asteroid impacts. The examined patch of soil is 3 centimeters (1.2 inches) across. The large, circular pebble in the lower left corner is approximately 3 millimeters (.12 inches) across, or about the size of a sunflower seed. This color composite was obtained by merging images acquired with the orange-tinted dust cover in both its open and closed positions. The blue tint at the lower right corner is a tag used by scientists to indicate that the dust cover is closed.

Original Source: NASA/JPL News Release