Environment

Hi-tech mooring records ocean acidity beneath Antarctic ice

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It's the first time that both a CO2 and pH sensor have been deployed in the continental shelf waters of the Southern Ocean
E. Shadwick/VIMS
Schematic of the various sensors and floats on Dr. Elizabeth Shadwick's 435 meter-long mooring
VIMS
VIMS Assistant Professor Elizabeth Shadwick (holding yellow rope) helps deploy her mooring, containing CO2, temperature, salinity and pH sensors
VIMS
It's the first time that both a CO2 and pH sensor have been deployed in the continental shelf waters of the Southern Ocean
E. Shadwick/VIMS
The pH of surface seawater averaged around 8.2 for millions of years. Since  the Industrial Revolution, it has been falling rapidly.  A drop of 0.1 pH units represents a roughly 25% increase in acidity.
VIMS
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Researchers from the Virginia Institute of Marine Science have deployed an innovative, sensor-studded mooring – as tall as the Empire State Building – beneath waters in Antarctica usually inaccessible through the winter.

Oceans play a major role in soaking up the carbon dioxide added to the atmosphere by fossil fuels and other human activities. In fact, the oceans have absorbed about a third of this CO2, with the Southern Ocean in Antarctica taking a starring role by soaking up almost half the total emissions taken in by seawater.

This is great news for the atmosphere, but the bad news is that CO2 increases the acidity of seawater, and marine life is sensitive to this acidity.

Scientists are particularly concerned about microscopic organisms at the bottom of the food web, such as krill, which impact animals further up the chain, including penguins, fish, seals and whales. Shipboard measurements from recent Antarctic summers suggest that rising CO2 concentrations could begin harming animals that form shells or skeletons from calcium carbonate minerals by around 2070.

This projection doesn't take the winter months into account at all, and scientists are concerned that the winter months could pose an even greater threat to local marine life. In winter, algal blooms release CO2 into the water through respiration or decay rather than removing CO2 from the water through photosynthesis and the other new growth cycles that occur in summer.

"Using sparse observations of wintertime conditions, our models predict the Southern Ocean will become under saturated with respect to carbonate by the year 2030," said Dr. Elizabeth Shadwick.

It's clear that gathering a broader and more accurate data set is critical to clarifying these predictions. The mooring, which is anchored to the seafloor in around 1,600 ft (487.68 m) of water, carries an array of hi-tech sensors that record the temperature and concentrations of dissolved carbon dioxide, salinity and pH levels of the south polar waters. The data will be stored in waterproof memory cards until the line is retrieved.

If the line performs as promised, it will extend the amount of information usually gathered in the region from the brief, ice-free period of summer (when research and supply ships can enter the area) to the entire year.

Dr. Shadwick and marine technician Olivia De Meo deployed the mooring last month from the deck of the research vessel Laurence M. Gould. "This is the first time that both a CO2 and pH sensor have been deployed in the continental shelf waters of the Southern Ocean," Dr. Shadwick told New Atlas. "The CO2 system in seawater has four parameters that can be measured directly, [but] for now, only two of these (CO2 and pH) can be measured autonomously at depth."

VIMS Assistant Professor Elizabeth Shadwick (holding yellow rope) helps deploy her mooring, containing CO2, temperature, salinity and pH sensors
VIMS

The researchers plan to recover the mooring in early May, at the same time deploying a second, identical mooring. This will be recovered the following December.

Retrieval involves using stored GPS coordinates to re-locate the mooring, which is tethered well below the water surface. The team will then free it from its seabed tether by pinging a release mechanism with an acoustic signal. The mooring should then float to the surface, where crewmembers will hook it with a grapple and hoist it aboard.

Dr Shadwick told New Atlas the project is not without risk. "The surface float is at about 20 meters below the sea surface, which should keep the mooring out of the way of sea-ice through the winter. But if a large (or even not so large) iceberg were to float by, it would likely take out the mooring entirely, or drag the instrument packages down into much deeper water where they would be damaged. We have chosen a location where this is unlikely, but it is always a risk with working in the Antarctic."

The mooring was designed in collaboration with Columbia University and with input from the Australian-based Antarctic Climate & Ecosystems CRC. It now lies within the study area of the Palmer Antarctic Long-Term Ecological Research program.

Data from the mooring should lead to a better understanding of the impact of climate change on the Earth's oceans, and help with impact predications.

Source: Virginia Institute of Marine Science

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6 comments
watersworm
"The low level of PH"... is never mentionned. For information a 7 PH level is neutral (neither acidic, nor alcalin), and the "mean" (whatever it...means) PH level of oceans is something like 7,8 (on logartimic scale !) That is not at all "acidic"
MartinVoelker
Ocean acidification - and the fact that much of the CO2 produced by our industrial activity and the burning of fossil fuels is going into the oceans - is overlooked. The impact on shellfish could be massive. NOAA’s Pacific Marine Environmental Laboratory is also working on that.
Ken Brody
CO2 dissolves much more in cold water than in warm water. The current level of atmospheric CO2 is under 400 parts per million - it's a trace gas. In the carboniferous era it was as high as 4000 ppm, yet shelled organisms flourished in the oceans then (ammonoids, corals, brachiopods, etc.). Finally, krill are shrimp-like creatures about ¾ inch long, hardly microscopic. Marine shells contain calcium, which does dissolve in acids. The ocean is alkaline, not acidic, and it is likely to stay that way.
habakak
Bull-twang. As soon as I see the world 'models' I know whatever is being said is wrong. Models NEVER represent the real-world and ALWAYS lack all the necessary pieces to make a valid prediction. We still don't know nearly enough to create models of the how CO2 is affecting the ocean.
MarkDonners
Clownish bunch of wannabe armchair scientists on here with an IQ as low as Trump who have done no research other than their prejudices, desperately trying to deny global warming and who don't have a clue what they are talking about. This is not a geological event (The Permian extinction which almost wiped out all life forms occurred because of massive CO2 release which was too fast and that's what you're wishing on the Earth) this is catastrophic release of CO2 by humans condensed into a short 100 years. 30+ billion tons of CO2 more than the 20 billion tons that natural systems can recycle, released into the upper atmosphere and oceans annually is NOT a natural event, and the planet does not have mechanisms to deal with that kind of assault. CO2 absorbed by the oceans increases the acidity of the oceans, CO2 is a greenhouse gas (yes it is always a trace gas but still acts as a greenhouse gas), this is called physics, like when you set yourself on fire you burn, dweebs, and you don't have to be a scientist to observe the massive harmful effects worldwide on oceans, forests, wildlife, and ice sheets with much fiercer storms, droughts, and ocean rise.