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Expeditions Blogs 2011 Planetary Lake Lander Expedition A Look below the Surface
A Look below the Surface
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Titan
Posted:   12/19/11
Author:    Henry Bortman

Summary: A team of scientists has traveled to remote Laguna Negra in the central Andes of Chile to test technologies that could one day be used to explore the lakes of Titan. Astrobiology Magazine's Expeditions Editor, Henry Bortman, provides a first-hand account of their progress.


Erich Fleming (l), Ruben Sommaruga and Alex Echeverria row out onto Laguna Lo Encañado – their boat is still awaiting its motor – to collect water samples. Credit: Henry Bortman
A team of scientists has traveled to remote Laguna Negra in the central Andes of Chile to test technologies that could one day be used to explore the lakes of Titan. The Planetary Lake Lander (PLL) project is led by Principal Investigator Nathalie Cabrol of the NASA Ames Research Center and the SETI Institute, and is funded by the NASA Astrobiology Science and Technology for Exploring Planets (ASTEP) program. This three-year field campaign will design and deploy a lake lander at Laguna Negra, which is a particularly vulnerable system where ice is melting at an accelerated rate. In addition to preparing us for Titan, the study will also help answer questions about how deglaciation affects life in glacial lakes. During the 2011 field campaign, Astrobiology Magazine's Expeditions Editor, Henry Bortman, is providing a first-hand account of the team's work through blogs and images.



Lago Lo Encañado
Thursday, December 1, 2011

The primary research site for the 2011 Planetary Lake Lander field campaign is Laguna Negra, near the shore of which the PLL base camp is located. Laguna Negra (black lagoon) is so-named because it is so clear that at times its surface appears black.

But members of the PLL science team today began their exploration of a second nearby lake, Laguna Lo Encañado (rough translation: lagoon in a canyon). Unlike Laguna Negra, Laguna Lo Encañado is opaque, sea-green in color, and lies at the end of a long valley containing significant wetlands.

Angela Detweiler collects samples of photosynthetic bacteria in the wetlands at the inlet to Laguna Lo Encañado. Credit: Henry Bortman

Until recently, Laguna Negra spilled over into Laguna Lo Encañado, which lies 200 meters lower in elevation. But the decrease in precipitation in the region and the shrinking of the Echaurren glacier, effects of rapid climate change, have caused the water level of Laguna Negra to drop several meters in only a few years.

Damaging UV radiation at 8500 feet above sea level, where Laguna Negra and Laguna Lo Encañado are situated, is much higher than at lower elevations. The difference between the two lakes, turbid Laguna Lo Encañado and transparent Laguna Negra, provides a valuable point of comparison for studying the strategies organisms employ to cope with this intense radiation.

The silt that washes into Laguna Lo Encañado absorbs UV radiation. Organisms living there don’t need to work as hard as do organisms in Laguna Negra to generate protective biological sunscreen compounds. Nor do they have to put as much energy into repairing DNA damage that exposure to UV radiation can cause.

Erich Fleming and Angela Detweiler, PLL team members based at the SETI Intitute and the NASA Ames Research Center (ARC) in Moffett Field, California, study the photosynthetic microbes that live in the two lakes. These organisms are capable of producing protective compounds to mitigate the effects of UV.

A panoramic view of Laguna Lo Encañado and the green valley that feeds into it. The Echaurren glacier can be seen in the upper right. Credit: Henry Bortman



Ruben Sommaruga, a professor of limnology at the University of Innsbruck, in Austria, studies the organisms that live in alpine lakes, among them small, shrimp-like crustaceans known as copepods. Copepods obtain some of their UV-protective compounds by eating the microbes that live alongside them in the lakes. But when that doesn’t provide sufficient protection, they generate their own protection in the form of carotenoids, which turns them red. These same carotenoid compounds are found in carrots and are responsible for giving them their characteristic orange color.

A engineering drawing of the Titan Mare Explorer craft proposed as a future NASA mission. Credit: Proxemy Research
Juvenile copepods – copepods go through many different stages before reaching adulthood – have not yet developed mouths, however, so they have no way to ingest protective compounds. In recent years scientists have learned that, at birth, juvenile copepods receive packages of protective compounds from their parents, to increase their chances of survival into adulthood.

Incidentally, all of us at PLL Base Camp are using the lake as the source of our drinking water. Which means we’re drinking a lot of copepods. We can see them, tiny little red dots floating around in our water bottles. To protect ourselves from UV, though, we still have to slather on sunscreen.

Quote of the day: “Now we have a system.”

A Close-up Look below the Surface

Friday, December 2, 2011

One of the goals of the Planetary Lake Lander Project is to develop technology that could be applied to a future mission Saturn’s giant moon Titan.

The Titan Mare Explorer (TiME) mission, proposed by Ellen Stofan of Proxemy Research, in Rectortown, Va., would land an autonomous spacecraft on and sail across one of Titan’s methane lakes, capturing photographs and taking measurements both above and below the lake’s surface. This proposed mission is one of three funded for further design development as the next possible NASA Discovery mission.

David Wettergreen tests his prototype underwater microscopic camera along the southern shore of Laguna Negra. Credit: Henry Bortman

Over the three-year course of the PLL project, engineers will develop a floating robot with capabilities similar to those that will be required by TiMe or a similar mission to Titan. The Planetary Lake Lander will be able to respond autonomously to scientifically interesting events in the rapidly changing glacial-lake environment of Laguna Negra. Robotic autonomy will be important to any Titan mission because Titan is too far from Earth for scientists here to receive data from a spacecraft on Titan and to respond with real-time commands. A robot exploring one of Titan’s lakes will need to operate on its own.

But for the first year, the Planetary Lake Lander will be under human control. It will remain behind at Laguna Negra when the PLL team leaves in mid-December, deploying a package of instruments that for a three-month period will continuously monitor conditions above and below the surface of Laguna Negra, sending its data, on demand, back to engineers at NASA Ames Research Center.

Onboard the PLL during this initial 3-month stint will be a 5-megapixel camera, remotely controllable; a meteorological station to track weather conditions through the summer months; and a sonde, a package of instruments for measuring water temperature, salinity, pH and other lake-water characteristics at various depths.

Future posts will report on the deployment of the pontoon (the floating platform) and the instruments that will be installed on it. But all this was not yet in place in the early days of the PLL field season. What did get tested early on, briefly, was a microscopic underwater camera designed to give a very close-up look at what’s lurking beneath the surface of Laguna Negra.

After a few days of clear blue skies, clouds began building up in the afternoons. The gravel beach in the lower right, a short walk from base camp, has been dubbed La Playa. Credit: Henry Bortman

David Wettergreen of Carnegie Mellon University in Pittsburgh, Pa., made a quick stop at the PLL base camp today to try out the camera, which lives inside a watertight metal housing. The 15-micron-per-pixel camera can see extremely small details: a single human hair appears 8 pixels wide.

The good news: the underwater test worked. The not so good news: mostly what it saw was bubbles. Not even a lonely copepod ventured by during the test. Later, however, back on shore, Wettergreen pointed the camera at a small plastic bottle filled with copepods from the lake, and beautifully detailed images of the tiny swimming crustaceans sprung to life.

The underwater camera will not be part of the instrument package deployed on the PLL at the end of the first field season, but it will be integrated into the PLL in future years.

Meanwhile, on the quality-of-life front, still no shower. Or bathroom. There are workarounds. Instead of a relaxing, warm shower, a quick jump in the freezing cold lake does wonders. For the faint of heart, pouring a bottle of water over one’s head also works. As for the bathroom, if you’ve ever gone backpacking…

Quote of the day: “Ve haf vays of making ze radios talk.”

 


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