The desperate race to cool the ocean before it’s too late

Technologyreview.com, By Holly Jean Buck, April 23rd

Holly Jean Buck is a fellow at UCLA’s Institute of the Environment and Sustainability. This is an adapted excerpt from her upcoming book After Geoengineering: Climate Tragedy, Repair, and Restoration (September 2019, Verso Books).

Coral reefs smell of rotting flesh as they bleach. The riot of colors—yellow, violet, cerulean—fades to ghostly white as the corals’ flesh goes translucent and falls off, leaving their skeletons underneath fuzzy with cobweb-like algae.

Corals live in symbiosis with a type of algae. During the day, the algae photosynthesize and pass food to the coral host. During the night, the coral polyps extend their tentacles and catch passing food. Just 1 °C of ocean warming can break down this coral-algae relationship. The stressed corals expel the algae, and after repeated or prolonged episodes of such bleaching, they can die from heat stress, starve without the algae feeding them, or become more susceptible to disease.

Australia’s Great Barrier Reef—actually a 2,300-kilometer (1,400-mile) system made up of nearly 3,000 separate reefs—has suffered severe bleaching in the past few years. Daniel Harrison, an Australian oceanographer looking at what might be done to buy more time for the Great Barrier Reef, says the situation is getting dire. “There might be as little as 25% of shallow-water coral cover left from pre-anthropogenic times. We don’t really know, because nobody started surveying before 1985,” he tells me. “You’ve got less than 1% of the ocean in coral reefs, and 25% of all marine life. We’re looking at losing all of that really quite quickly, in evolutionary terms. In human-lifetime terms.”

Coral reefs are not just about colorful fish and exotic species. Reefs protect coasts from storms; without them, waves reaching some Pacific islands would be twice as tall. Over 500 million people depend on reef ecosystems for food and livelihoods. Even if the temperature increase eventually stabilizes at 1.5 °C a century or two from now, it’s not known how well coral reef ecosystems will survive a temporary overshoot to higher temperatures.

The corals are like the canary in the coal mine.

The corals are like the canary in the coal mine, Harrison says: “They’re very temperature-sensitive. I really do think it’s just a harbinger of things to come. You know, the coral ecosystem might collapse first, but I think there might be quite a few more ecosystems that’ll follow it. Life is very resilient, but ecosystems as we know them aren’t.”

Read more about corals, cooling the ocean, and climate change

Acid Seas Threaten Creatures that Supply Half the World’s Oxygen

Ocean acidification is turning phytoplankton toxic. Bad news for the many species – us, included – that rely on them as a principal source of food and oxygen.

June 16th, 2014 By Martha Baskin and Mary Bruno, crosscut.com

What happens when phytoplankton, the (mostly) single-celled organisms that constitute the very foundation of the marine food web, turn toxic?

phytoplankton pseudonitzschia_Their toxins often concentrate in the shellfish and many other marine species (from zooplankton to baleen whales) that feed on phytoplankton. Recent trailblazing research by a team of scientists aboard the RV Melville shows that ocean acidification will dangerously alter these microscopic plants, which nourish a menagerie of sea creatures and produce up to 60 percent of the earth’s oxygen.

The researchers worked in carbon saturated waters off the West Coast, a living laboratory to study the effects of chemical changes in the ocean brought on by increased atmospheric carbon dioxide. A team of scientists from NOAA’s Fisheries Science Center and Pacific Marine Environmental Lab, along with teams from universities in Maine, Hawaii and Canada focused on the unique “upwelled” zones of California, Oregon and Washington. In these zones, strong winds encourage mixing, which pushes deep, centuries-old CO2 to the ocean surface. Their findings could reveal what oceans of the future will look like. The picture is not rosy.

Scientists already know that ocean acidification, the term used to describe seas soured by high concentrations of carbon, causes problems for organisms that make shells. “What we don’t know is the exact effects ocean acidification will have on marine phytoplankton communities,” says Dr. Bill Cochlan, the biological oceanographer from San Francisco State University oceanographer who was the project’s lead investigator. “Our hypothesis is that ocean acidification will affect the quantity and quality of certain metabolities within the phytoplankton, specifically lipids and essential fatty acids.”

Acidic waters appear to make it harder for phytoplankton to absorb nutrients. Without nutrients they’re more likely to succumb to disease and toxins. Those toxins then concentrate in the zooplankton, shellfish and other marine species that graze on phytoplankton.

Consider the dangerous diatom Pseudo-nitzschia (below). When ingested by humans, toxins from blooms of this single-celled algae can cause permanent short-term memory loss and in some cases death, according to Dr. Vera Trainer, an oceanographer with NOAA’s Fisheries Marine Biotoxins Program. Laboratory studies show that when acidity (or pH) is lowered, Pseudo-nitzschia cells produce more toxin. When RV Melville researchers happened on a large bloom of Pseudo-nitzschia off the coast of Point Sur in California, where pH levels are already low, they were presented with a rare opportunity, explains Trainer, to see if their theory “holds true in the wild.”

Multiple phytoplankton populations became the subjects of deck-board experiments throughout the Melville’s 26-day cruise, which began in mid-May and finished last week.

Another worrisome substance is domoic acid, a neuro-toxin produced by a species of phytoplankton. Washington has a long history of domoic acid outbreaks. The toxin accumulates in mussels and can wind up in humans. “Changes in the future ocean could stimulate the levels of domoic acid in the natural population,” says Professor Charles Trick, a biologist with Western University in Ontario, and one of the RV Melville researchers. Which means that the acidified oceans of tomorrow could nurture larger and more vigorous outbreaks of killer phytoplankton, which could spell death to many marine species.

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