The link to the original article is http://www.nature.com/nclimate/journal/vaop/ncurrent/full/nclimate1122.html

by Katharina E. Fabricius, Chris Langdon, Sven Uthicke, Craig Humphrey, Sam Noonan, Glenn De’ath, Remy Okazaki, Nancy Muehllehner, Martin S. Glas & Janice M. Lough

Reference: Fabricius KE, Langdon C, Uthicke S, Humphrey C, Noonan S, De’ath G, Okazaki R, Muehllehner N, Glas M, Lough JM (2011) Losers and winners in coral reefs acclimatized to elevated carbon dioxide concentrations. Nature Climate Change 1: 165-169

Published online 29 May 2011

Experiments have shown that ocean acidification due to rising atmospheric carbon dioxide concentrations has deleterious effects on the performance of many marine organisms1, 2, 3, 4. However, few empirical or modelling studies have addressed the long-term consequences of ocean acidification for marine ecosystems5, 6, 7. Here we show that as pH declines from 8.1 to 7.8 (the change expected if atmospheric carbon dioxide concentrations increase from 390 to 750 ppm, consistent with some scenarios for the end of this century) some organisms benefit, but many more lose out. We investigated coral reefs, seagrasses and sediments that are acclimatized to low pH at three cool and shallow volcanic carbon dioxide seeps in Papua New Guinea. At reduced pH, we observed reductions in coral diversity, recruitment and abundances of structurally complex framework builders, and shifts in competitive interactions between taxa. However, coral cover remained constant between pH 8.1 and ~7.8, because massive Porites corals established dominance over structural corals, despite low rates of calcification. Reef development ceased below pH 7.7. Our empirical data from this unique field setting confirm model predictions that ocean acidification, together with temperature stress, will probably lead to severely reduced diversity, structural complexity and resilience of Indo-Pacific coral reefs within this century.

Affiliations

Australian Institute of Marine Science, PMB 3, Townsville, Queensland 4810, Australia
Katharina E. Fabricius,
Sven Uthicke,
Craig Humphrey,
Sam Noonan,
Glenn De’ath &
Janice M. Lough
University of Miami Rosenstiel School of Marine and Atmospheric Science, 4600 Rickenbacker Causeway, Florida 33149, USA
Chris Langdon,
Remy Okazaki &
Nancy Muehllehner
Max-Planck Institute for Marine Microbiology, Department of Biogeochemistry, Celsiusstr. 1, 28395 Bremen, Germany
Martin S. Glas

Contributions

All authors were involved with either fieldwork or data analyses. K.E.F. initiated and designed the study and wrote the manuscript, with contributions from all others. C.L. and R.O. analysed the seawater chemistry, C.H., S.N., K.E.F. and J.M.L. collected and analysed the Porites data, C.L. the in situ coral growth data, K.E.F. and S.N. the reef community data, S.U. the sediments and foraminifera, N.M. and S.U. the seagrass and epibiont data, and G.D. and K.E.F. conducted the statistical analyses.
Competing financial interests

The authors declare no competing financial interests.

Correspondence to: Katharina E. Fabricius

http://data.iucn.org/dbtw-wpd/edocs/Bios-Eco-Mar-Cor-027.pdf

by Kaufman L, Sandin S, Sala E, Obura D, Rohwer F, and Tschirky T (2011)
Coral Health Index (CHI): measuring coral community health.
Science and Knowledge Division, Conservation International, Arlington, VA, USA.

There is a new tool for assessing coral healthwhich has just been released by Conservation International (CI) and is available for download free on an IUCN website (International Union for the Conservation of Nature). I find it very easy to read and understand, and this appears to me to have widespread potential for applicability and use around the world to get a much better idea of how our reefs are doing. I can’t wait to try it out on reefs near me and see how they rate (I have a guess, but still it will be fascinating to see). Cheers, Doug Fenner

Special thanks to Doug Fenner, coral-list

http://www.bbc.co.uk/news/science-environment-13605113#story_continues_1

31 May 2011 Last updated at 19:47 ET

By Richard Black Environment correspondent, BBC News

Clownfish, the spectacular tropical species featured in the movie Finding Nemo, appear to lose their hearing in water slightly more acidic than normal.

At levels of acidity that may be common by the end of the century, the fish did not respond to the sounds of predators.

The oceans are becoming more acidic because they absorb much of the CO2 that humanity puts into the atmosphere.

Scientists write in the journal Biology Letters that failing to move away from danger would hurt the fish’s survival.

“Avoiding coral reefs during the day is very typical behaviour of fish in open water,” said research leader Steve Simpson from the School of Biological Sciences at the UK’s Bristol University.

“They do this by monitoring the sounds of animals on the reef, most of which are predators to something just a centimetre in length.

“But sounds are also important for mate detection, pack hunting, foraging – so if any or all of those capacities are gone, you’d have a very lost fish,” he told BBC News.

Previous research has shown that fish also lose their capacity to scent danger in slightly more acidic seawater.
Experimental chamber The fish were put in a “choice chamber” that allowed them to swim away, or not, on hearing the noise

The team raised baby clownfish in tanks containing water at different levels of acidity.

One resembled the seawater of today, with the atmosphere containing about 390 parts per million (ppm) of carbon dioxide.

The other tanks were set at levels that could be reached later this century – 600, 700 and 900 ppm.

The more CO2 there is in the atmosphere, the more the oceans absorb – and the more they absorb, the more acidic the water becomes.

In this experiment, the fish could decide whether to swim towards or away from an underwater loudspeaker replaying the sounds of predators recorded on a reef, with shrimps and fish that would take a small clownfish.

In water with today’s levels of CO2, the fish spent three-quarters of the time at the opposite end of the tube from the loudspeaker.

But at higher concentrations, they showed no preference. This suggests they could not hear, could not decipher or did not act on the warning signals.

“The reef has been described as ‘a wall of mouths’ waiting to receive the clownfish,” said Dr Simpson.
Continue reading the main story
ACIDIFYING OCEANS
Ocean pH levels (Image: BBC)

The oceans are thought to have absorbed about half of the extra CO2 put into the atmosphere in the industrial age
This has lowered its pH by 0.1
pH is the measure of acidity and alkalinity
Liquids lie between pH 0 (very acidic) and pH 14 (very alkaline); 7 is neutral
Seawater is mildly alkaline with a “natural” pH of about 8.2
The IPCC forecasts that ocean pH will fall by “between 0.14 and 0.35 units over the 21st Century, adding to the present decrease of 0.1 units since pre-industrial times”

“What we have done here is put today’s fish in tomorrow’s environment, and the effects are potentially devastating.”

If it takes several decades for the oceans to reach these more acidic levels, there is a chance, the team says, that fish could adapt.

Whether that can happen is one of the outstanding questions from this research. Another is whether other species are similarly affected.

A third question is why the fish are affected by these slight changes in acidity.

There appears to be no physical damage to their ears; the team suggests there could be some effect on nerves, or maybe they are stressed by the higher acidity and do not behave as they otherwise would.

Further experiments are in train that may answer those questions.

Concern about ocean acidification has arisen considerably more recently than alarm over global warming; but already there is ample evidence that it could bring significant changes to ocean life.

The organisms most directly affected appear to be corals and those that make shells, such as snails.

Just this weekend, another team of researchers published findings from a “natural laboratory” in the seas off Papua New Guinea, where carbon dioxide bubbles into the water from the slopes of a dormant volcano.

This local acidity is too much for most corals; instead, an alternative ecosystem based on seagrasses thrives.

With carbon emissions continuing to rise, researchers predicted most reefs around the world would be in serious trouble before the end of the century.
More on This Story
Related Stories

Fish ‘at risk’ in acidified ocean 21 NOVEMBER 2009, SCI/TECH
Bubbling sea signals coral threat 29 MAY 2011, SCIENCE & ENVIRONMENT
Coral reefs heading into crisis 23 FEBRUARY 2011, SCIENCE & ENVIRONMENT
Recipe for rescuing our reefs 05 NOVEMBER 2008, SCI/TECH

Special thanks to Doug Fenner, Coral-list.

Published on Sunday, May 29, 2011

Carbon dioxide pollution adds to threat to world’s oceans and marine species
by Robin McKie, science editor

The infernal origins of Vulcano Island are easy to pinpoint. Step off the hydrofoil from Sicily and the rotten-egg smell of hydrogen sulphide strikes you immediately. Beside the quay, there are piles of yellow sulphurous rocks and chunks of pumice; the beach is made of thick, black volcanic sand; while the huge caldera that dominates the bay emits a constant stream of smoke and steam.

By the middle of the century there will probably be only a few pockets of coral left, in the North Sea and the Pacific. Millions of species of marine life will be wiped out. (Photo: Vladimir Levantovsky/Alamy) According to legend, this was the lair of the Roman god of fire, Vulcan, who gave his name to the island and subsequently to all other volcanoes. An early eruption here also provided history with one of the first recorded descriptions of a volcano in action.

But Vulcano’s importance today has nothing to do with the rock and lava it has spewed out for millennia. It is the volcano’s output of invisible carbon dioxide – about 10 tonnes a day – that now interests scientists. They have found that the gas is bubbling through underground vents and is making the island’s coastal waters more and more acidic. The consequences for sea life are grim with dozens of species having been eliminated.

That discovery is highly revealing, and worrying, because Vulcano’s afflictions are being repeated today on a global scale, in every ocean on the planet – not from volcanic sources but from the industrial plants, power stations, cars and planes that are pumping out growing amounts of carbon dioxide and which are making our seas increasingly acidic. Millions of marine species are now threatened with extinction; fisheries face eradication; while reefs that protect coastal areas are starting to erode.

Ocean acidification is now one of the most worrying threats to the planet, say marine biologists. “Just as Vulcano is pumping carbon dioxide into the waters around it, humanity is pouring more and more carbon dioxide into the atmosphere,” Dr Jason Hall-Spencer, a marine biologist at Plymouth University, told a conference on the island last week.

“Some of the billions of tonnes of carbon dioxide we emit each year lingers in the atmosphere and causes it to heat up, driving global warming. But about 30% of that gas is absorbed by the oceans where it turns to carbonic acid. It is beginning to kill off coral reefs and shellfish beds and threaten stocks of fish. Very little can live in water that gets too acidic.”

Hence science’s renewed interest in Vulcano. Its carbon dioxide springs – which bubble up like burst water mains below the shallow seabed – provide researchers with a natural laboratory for testing the global impact of ocean acidification. “These vents and the carbonic acid they generate tell us a great deal about how carbon dioxide is going to affect the oceans and marine life this century,” said Hall-Spencer. “And we should be worried. This problem is a train coming straight at us.”

Scientists estimate that oceans absorb around a million tonnes of carbon dioxide every hour and our seas are 30% more acidic than they were last century. This increased acidity plays havoc with levels of calcium carbonate, which forms the shells and skeletons of many sea creatures, and also disrupts reproductive activity.

Among the warning signs recently noted have been the failures of commercial oyster and other shellfish beds on the Pacific coasts of the US and Canada. In addition, coral reefs – already bleached by rising global temperatures – have suffered calamitous disintegration in many regions. And at the poles and high latitudes, where the impact of ocean acidification is particularly serious, tiny shellfish called pteropods – the basic foodstuff of fish, whales and seabirds in those regions – have suffered noticeable drops in numbers. In each case, ocean acidification is thought to be involved.

The problem was recently highlighted by the head of the US National Oceanic and Atmospheric Administration, Dr Jane Lubchenco. She described ocean acidification as global warming’s “equally evil twin”. It is a powerful comparison, though it is clear that of the two, the crisis facing our seas has received far less attention. The last UN climate assessment report was more than 400 pages long but had only two pages on ocean acidification – mainly because studies of the phenomenon are less well advanced than meteorological and atmospheric research in general.

The workshop, held last week on Vulcano, is part of the campaign to understand the likely impact of ocean acidification. Dozens of young oceanographers, geologists and ecologists gathered for the meeting run by the Mediterranean Sea Acidification (MedSeA) programme. Dr Maoz Fine, of Bar-Ilan University in Israel, reported work on coral reef organisms that had been exposed to waters of different levels of acidity, temperature and light in his laboratory.

“We found that species of coral reef respond differently to rising carbon dioxide levels,” he said. “Bigger corals suffer but survive while smaller, branching varieties become less able to fight disease and die off. That sort of thing just makes it even more difficult to predict exactly what is going to happen to our oceans.”

Few scientists doubt that the impact on reefs will be anything short of devastating, however. The Caribbean has already lost about 80% of its coral reefs to bleaching caused by rising temperatures and by overfishing which removes species that normally aid coral growth. Acidification threatens to do the same for the rest of the world’s coral reefs.

“By the middle of the century there will probably be only a few pockets – in the North Sea and the Pacific. Millions of species of fish, shellfish and micro-organisms will be wiped out,” said Fine.

Acidification has affected the oceans in the past. However, these prehistoric events occurred at a far slower rate, said Dr Jerry Blackford of Plymouth Marine Laboratory. “The waters of the world take around 500 years to circulate the globe,” he said. “If carbon dioxide was rising slowly, in terms of thousands of years, natural factors could then compensate. Sediments could buffer the carbonic acid, for example.”

But levels of carbon dioxide are rising much faster today. By the end of the century, surface seawater will be 150% more acidic than it was in 1800. “There is simply not enough time for buffering to come into effect and lessen the impact,” said Blackford. “The result will be significant acid build-up in the upper parts of the oceans which, of course, are the parts that are of greatest importance to humans.”

A vision of the seas we are now creating can be seen at Vulcano. On the eastern side of its main bay, beyond an open-air thermal spa filled with elderly bathers wallowing in volcanically heated mud, there is a long stretch of black sand.

Just offshore, in about four feet of water, silver beads of carbon dioxide stream up from stones that lie over an underground vent. The water, although cold, looks like a huge, frothing Jacuzzi. Water here is highly acidic and there is no marine life around the vent – not even seaweed.

“The acidity here is far greater than even the worst ocean scenario for 2100, so we have to be careful about making comparisons,” said Dr Marco Milazzo, of Palermo University. “However, currents carry that acid water round the bay and it becomes more and more dilute. We can then study waters which reflect the kind of acidity we are likely to get at the end of the century.”

Milazzo and his colleagues have placed open boxes containing coral and other forms of marine life in the waters round the bay and monitor the effects of the different levels of acidity in the sea water on these samples and also on the bay’s natural marine life. “When I look one way, out to sea, where there is little acidity, the plant life is rich in reds, whites, greens and other colours. There is abundance and variety in the habitat,” said Milazzo.

“However, when I look the other way – back towards the carbon dioxide vent – that habitat gets less and less varied as the water gets more acidic. It is reduced to a dark brown bloom of macro-algae. There is no richness or variety here. In effect I am looking at the oceans of tomorrow. It is profoundly depressing.”
DEEP WATER

Acidity is measured by its pH (power of hydrogen) value. Fresh water has a pH reading of 7. Readings below that are considered to be acidic. Those above 7 are alkaline. Surface sea water had a reading of 8.2 a century ago. Today it has dropped to 8.1 because so much carbon dioxide has been absorbed by the world’s oceans. That may seem a small amount but the pH scale is logarithmic which means that 0.1 difference actually represents an increase in acidity of 30%. By the end of the century, the pH of surface sea water could have dropped to 7.8, which represents a decrease in alkalinity – or an increase in acidity, depending on your viewpoint – of around 150%.