Houston, We´ve Had a Conference!
The conference portions were Texas-sized, with more science presented than any single space cowboy could lasso. Here are a few Lone Star stand-outs:
Lava-tube walls are often decorated with a unique variety of patterns, including gold-colored veins, white dots, blue-green stalactites, and pink hexagons. These deposits were thought to be the result of purely chemical processes, but according to caving mavens Penny Boston of New Mexico Tech and Diana Northup of the University of New Mexico, many of these patterns are actually “bug poop” left behind by microbes as they eat away at rock walls to obtain nutrients. “A lot of morphologies that we might have overlooked in the past, that look very mineral, actually have a rich biodiversity,” said Northup. With their colleagues, Boston and Northup are using computer models to simulate the pattern formation. By narrowing in on the specific biological processes responsible for creating them, they can learn how long these patterns persist and remain detectable as biosignatures. These understandings, they hope, will one day prove valuable in robotic life detection efforts in lava tubes on other worlds.
It’s Miller Time
Organisms that eke out a living on sea cliffs in Beer, England are exposed to wind, rain, salt, UV radiation, and dry spells. The harsh conditions may be one reason the diversity of life there is so low – not many organisms have “The Right Stuff” for sea cliff survival. Charles Cockell of the Open University in the UK explained that life on these bare rocks is mostly cyanobacteria, and studying them may tell us about the limits for life on other planets. What are the different mechanisms the cyanobacteria use in order to survive where few else can? One thing’s for certain – if anyone could use a beer after a hard day, it’s the life on sea cliffs in Beer, England.
When looking for life in the universe, don't expect to find quirky things like naked molerats or Woody Allen. So says Charley Lineweaver of the Australian National University, who pointed out that life follows unique evolutionary paths based on a variety of influences, and so we can’t expect to find alien life that looks anything like life on Earth. Lineweaver disagrees with scientists such as Simon Conway-Morris, who believe that certain body forms – wings, eyes, brains -- arise again and again because those are ideal solutions that biology has devised to interact with the environment.
A Warm and Wet Mars?
Brian Toon of the University of Colorado and Jim Kasting of Penn State debated whether Mars could have once had a warm period that allowed liquid water to persist on the planet’s surface. Features such as Nirgal Valles appear to have been formed by flowing liquid water, and Toon argued that these features could be the result of asteroid or comet impacts that melted subsurface ice. In this 'impact hypothesis', canyon-like features could have been carved quickly by immense floods. Jim Kasting, however, believes that many of the features identified on Mars would have taken much longer to form. One primary example that Kasting used was Nanedi Valles on Mars, which Kasting referred to as "essentially a Grand Canyon, on a slightly smaller scale." Kasting estimates that it took roughly 5 million meters of water to form the Grand Canyon on Earth over 17 million years. On Mars, Kasting says much more water would have been needed to form Nanedi Vallis than what would have been generated by an impact. Kasting and Toon also discussed problems with the greenhouse models of Mars, and why some scientists don't think such an atmosphere would have warmed the planet. More carbon dioxide would have raised the temperature, but more clouds would have reflected sunlight back into space, cooling the planet. Toon noted: "We've spent 30 years on the greenhouse effect and no one has solved the problem in a credible way so far. On the greenhouse problem we're just drifting into deeper and deeper complexity."
TWEEL to Reel in Mars Life
The Labeled Release (LR) experiment conducted in 1976 by NASA’s two Viking landers added nutrients to martian soil and analyzed the gases released, looking for evidence of life. Both spacecraft returned positive results, and although in the 40-plus years since a scientific consensus has emerged that Viking did not find martian life, LR Principal Investigator Gil Levin remains unshaken in his belief that it did. Now Levin wants NASA to return to one of the Viking landing sites with a new experiment to settle the question. TWEEL (Twin Wireless Extraterrestrial Experiment for Life) would consist of a set of sterilized dart-like probes that would contain two chirally distinct sets of nutrients, in different chambers. (Life’s building-block molecules come in right- and left-handed, or “chiral” versions, but life’s basic structures incorporate only one chiral alternative of each: L (“left-handed”) amino acids and D (“right-handed”) sugars.) Shot downwind to prevent contamination, upon impact TWEEL’s darts would release the nutrients into the soil, radioing results back to the lander. If only one of the two sets of chiral nutrients induced a reaction, Levin said it would be nearly incontrovertible evidence of life on Mars.
Bringing Back the Right Stuff
During discussion of the National Research Council’s Astronomy and Astrophysics Decadal Survey, Wendy Calvin of the University of Nevada at Reno said the Mars exploration program is now shifting its sights to missions beyond the upcoming Mars Science Laboratory. "In a decade of Mars exploration we've moved from follow the water," Calvin explained. "We can now move into the next phase - seeking signs of life." One way to do this is to bring a sample of Mars rock and soil back to Earth for laboratory analysis, allowing researchers to employ far more sophisticated tests than would be possible to include on a spacecraft. Decadal survey chairman Steve Squyres got some serious pushback from the audience when he reported that the overwhelming consensus within the Mars science community was that sample return should take priority over testing for life on Mars (in-situ tests). Among those who argued in favor of in-situ testing was Carl Pilcher, former senior scientist for astrobiology at NASA headquarters and current director of the NASA Astrobiology Institute. “There is something wrong,” he said, with trying “to determine the answer to the most important question about Mars from a kilogram of Mars” – the amount of martian rock and soil that could be brought back to Earth – without first conducting life-detection tests in “a bunch of different places” on Mars to determine which material to bring back.
Not much is known about the region of the atmosphere where commercial flights plan to shuttle tourists into space, said David Grinspoon, curator of astrobiology at the Denver Museum of Nature & Science. The mesosphere extends about 50 to 90 kilometers above the Earth’s surface, and it’s an important atmospheric region when it comes to climate change, but we are largely ignorant of what happens there because it’s not accessible by current instruments. “The ‘ignorosphere’ is too high for aircraft and weather balloons, and too low for satellites,” Grinspoon noted. Commercial reusable suborbital spacecraft therefore could be used not only for space tourism, but to help scientists gather valuable information. The frequency of tourist flights also could allow scientists to reliably test and certify new instruments for astronomical and planetary observation.
And by the way, if do you hope to fly as a space tourist, the projected total flight time is 2.5 hours, but the total time spent weightless is just 5 minutes.
Hibernation and suspended animation aren’t being considered in current NASA plans for human space exploration, but many science fiction stories feature astronauts waking up like Sleeping Beauty, barely having aged a day after hundreds of years of space travel. Ben Best, president of the Cryonics Institute, talked about the promise and problems with this technology. According to the “Q10” rule, every 10 degree Celsius drop in body temperature reduces the metabolic rate by half.
Andrew Schuerger of NASA’s Kennedy Space Flight Center and the University of Florida described a deliberately dirty field trip. The Mars Institute’s Moon-1 Humveee Rover was driven nearly 500 kilometers (311 miles) on sea ice along the Northwest Passage in the Canadian Arctic. The Humvee was not sterilized beforehand – the interior was ripe with dirt, bacteria and fungi. The scientists wanted to see if human-associated microbes would become airborne and contaminate the environment far from the Humvee’s path. Tests of the pristine snow showed few if any microbes were released into the surrounding environment from the vehicle, and Schuerger said this means that elaborate pre-sterilization procedures for space exploration vehicles may not be necessary. Even astronauts walking outside their rovers on Mars won’t need to fret – all the contamination would be on the inside of the spacesuit, while the outside of the suit would be continually sterilized by UV radiation.
Aliens 20 Light Years Away?
Gleise 581, a red dwarf star 20 light years away from Earth, has at least four planets orbiting it. Two of those planets may be habitable – planets “c” and “d”. Planet “c” may have a runaway greenhouse atmosphere, like Venus, due to its orbital location, but planet “d” may be more Earth-like.
A False Positive for Life
Earth would not have oxygen without life. Photosynthetic organisms produce oxygen as a waste product when they breathe in carbon dioxide, and ultraviolet (UV) light in the upper atmosphere turns the oxygen into the protective ozone layer. If astronomers detect oxygen (O2) and ozone (O3) on a far-distant planet, chances are that planet has life. However, according to Shawn Domagal-Goldman of the University of Washington, photosynthetic life is not the only generator of ozone. UV radiation can also create O3 by breaking oxygen molecules free from other gases (a process called photodisassociation, or photolysis). It’s a slow process to build up ozone this way, especially because UV light can simultaneously be destroying the O3 molecules as they’re making them. But, like a dripping faucet eventually filling a sink, ozone levels could build up over time. This kind of ozone accumulation could be detectable, and therefore could potentially fool us into thinking an extrasolar planet has life.
The Future of Astrobiology
Chris Impey of the University of Arizona predicted where astrobiology is headed in the next 50 years. He has high expectations for private space, boldly stating, "There will be 1,000 space tourists by 2025." He imagines a world where private companies will play a role in exploring our solar system in searching for signs of life. Wealthy patrons of astrobiology will get tired of waiting for answers to questions like “Is there life on Mars or Europa?” The resources of these private (and impatient) individuals may help scientists explore some of the most astrobiologically significant locations in near and far space. By 2060 - Voyage to Alpha Centauri!
Note: Aaron Gronstal and Henry Bortman contributed to this report
For a broad overview of the conference, visit http://astrobiology.nasa.gov/articles/abscicon-2010-a-success/