Deep Sea Exploration May Hold Clues to Climate Warming, Origins of Life, and More
The tragic implosion of the deep-sea tourist submersible Titan on June 18 illuminated the dangers of deep-sea expeditions. At the same time, the notion of exploring the ocean's depths听鈥撎齩ne of the last unknown frontiers 鈥 captured the world鈥檚 imagination. What unknown species live in its deepest waters? Are our ocean ecosystems affected by a warming climate? What mysteries can we solve through deep-sea exploration? What answers can be found on听the ocean鈥檚 floors?
鈥淭he deep ocean is a mysterious and other worldly place where much is unknown, so of course people are drawn to it,鈥 says Stephen MacAvoy, associate professor in 猫咪社区app University鈥檚 Department of Environmental Science. In the late 1990s and early 2000鈥檚, MacAvoy鈥檚 research took him to the Gulf of Mexico to conduct research on deep-sea tubeworm communities (some six-feet-long and hundreds of years old) and the food webs that sustain them.
We asked Professor MacAvoy to share his experiences in deep sea research and explain some of the dangers and rewards faced by scientists researching deep sea biodiversity.
Q. We know more about the surface of the moon than we do about the deep ocean. Why is the deep ocean still so unexplored?听
A. While we know a fair amount of the bathymetry (underwater topography) of the oceans, it is very hard to get down there. As you descend, the pressure increases by one atmosphere (14.7 pounds per square inch) every 33 feet, and only a few submersibles in the world can reach the deep ocean off the continental shelves. Additionally, even if you do manage to get to the bottom, it is completely dark.
Q. What type of deep-sea research did you conduct?听
A. The work I was involved with investigated communities of animals first discovered in the late 1980s and early 1990s.听These communities are in the Gulf of Mexico, and those I helped investigate are around one mile down from the ocean鈥檚 surface (but they extend to much greater depths).听Creatures there use chemical energy from hydrogen sulfide and methane to make sugar (chemosynthesis) as opposed to light energy used to make sugar (photosynthesis).听We call these "hydrocarbon seep" communities because they seem to form where oil naturally seeps from the sediments.
Down there in the complete darkness and freezing cold (a few degrees above 0掳C), there were large densities of entirely new animal species living with entirely new bacterial species.听The communities were complex, diverse, and stable for long periods.听Some worm species (Lamellibrachia luymesi, Seepiophila jonesi, and Escarpia laminata) were six feet long and hundreds of years old!听My job was to figure out food webs around the communities and determine how important chemosynthetic production was to the surrounding deep ocean.
Q. What was the experience like?听听
A. The submersible we used, the Johnson Sea Link, held four people and was mostly used in the oil and gas industry.听It was perfect for exploring the deep-sea communities though because it had suction and clamping appendages, video and still photography, excellent lighting, a rotating array of collection chambers, and could take water samples at depth through probes.听The rear of the submersible was very tight and was like laying down in a six-by-two-foot听metal pipe. The front chamber was an acrylic sphere allowing full visibility in almost all directions.听We could communicate with the support ship, but GPS doesn't work below water, so there was some guess work about where you were and where the support ship was.听It was dangerous but the crews were amazing and made sure the scientists didn't mess things up too badly!听
Q. What discoveries might be found under the sea? Is it possible that deep-sea exploration could hold some clues to critical issues like climate change and extinction?听听
A. Science questions abound in the deep-sea sphere. How important is chemosynthesis (making sugar from chemical energy) as opposed to photosynthesis (making sugar from light鈥檚 energy) in deep sea communities?听What kind of minerals exist as the Earth's crust transitions to the semi-molten mantle? Could life have originated in deep sea hydrothermal vents where biological building blocks and chemical energy abound? How and where does the deep sea synthesize or concentrate rare-earth minerals? These are all big questions, and to find the answers, people must go down there. But it is not taken lightly and is understood to be dangerous.
Scientists are investigating climate change and extinction by using ocean sediment cores.听One of the neat things about the sediments is that you can investigate extinctions and climate for the same time period and test for links between the two.
Another area of interest is mining the ocean for rare earth metals for use in the electronics industry (including the growing alternative energy sector).听Deep hydrothermal vents occur in areas where the sea floor is spreading and may be home to organisms yielding clues to the origins of life.听So, there are lots of big mysteries to be investigated, and I have no doubt that more surprises are in store as exploration continues.