Diverse coral communities persist, but bioerosion escalates in Palau’s low-pH waters
From Woods Hole Oceanographic Institute :
As the ocean absorbs atmospheric carbon dioxide (CO2) released by the burning of fossil fuels, its chemistry is changing. The CO2 reacts with water molecules, lowering the ocean’s pH in a process known as ocean acidification. This process also removes carbonate ions, an essential ingredient needed by corals and other organisms to build their skeletons and shells.
Will some corals be able to adapt to these rapidly changing conditions? If so, what will these coral reefs look like as the oceans become more acidic?
In addition to laboratory experiments that simulate future ocean conditions, scientists are studying coral reefs in areas of the ocean where low pH is naturally occurring to try and answer important questions about ocean acidification, which threatens coral reef ecosystems worldwide.
One such place is Palau, an archipelago in the far western Pacific Ocean. The tropical, turquoise waters of the Palau Rock Islands are naturally more acidic due to a combination of biological activity and the long residence time of seawater within its maze of lagoons and inlets. Seawater pH within the Rock Island lagoons is as low now as the open ocean is projected to be as a result of ocean acidification near the end of this century.
A new study led by scientists at Woods Hole Oceanographic Institution (WHOI) found that the coral reefs there seem to be defying the odds, showing none of the predicted responses to low pH except for an increase in bioerosion — the physical breakdown of coral skeletons by boring organisms such as mollusks and worms. The paper is to be published June 5 in the journal Science Advances.
‘Based on lab experiments and studies of other naturally low pH reef systems, this is the opposite of what we expected,’ says lead author Hannah Barkley, a graduate student in the WHOI-MIT joint program in oceanography.
Experiments measuring corals’ responses to a variety of low pH conditions have shown a range of negative impacts, such as fewer varieties of corals, more algae growth, lower rates of calcium carbonate production (growth), and juvenile corals that have difficulty constructing skeletons.
‘Surprisingly, in Palau where the pH is lowest, we see a coral community that hosts more species, and has greater coral cover than in the sites where pH is normal,’ says Anne Cohen, a co-author on the study and Barkley’s advisor at WHOI. ‘That’s not to say the coral community is thriving because of it, rather it is thriving despite the low pH, and we need to understand how.’
When the research team compared the communities found on Palau’s reefs with those in other reefs where pH is naturally low, they found increased bioerosion was the only shared common feature.
‘Our study revealed increased bioerosion to be the only consistent community response, as other signs of ecosystem health varied at different locations,’ Barkley says.
‘This is important because on coral reefs, the balance between calcium carbonate production and removal by bioerosion and dissolution is very tight,’ adds Cohen. ‘So even if rates of production are not affected by ocean acidification — as we see on Palau — an increase in bioerosion can shift reefs to a state of net calcium carbonate removal, threatening their survival.’
Rapidly changing chemistry
Since the beginning of the Industrial Revolution, ocean pH has fallen by 0.1 pH units, which represents an increase in acidity of approximately 30 percent. For marine life that has evolved over millions of years in relatively stable pH conditions, this kind of rapid change doesn’t allow for much time to adapt. By the end of this century, pH levels are projected to be nearly 150 percent more acidic, resulting in a pH that the oceans haven’t experienced for more than 20 million years.
There are several sites around the world where CO2 is released by undersea volcanic activity that vents up from the seafloor through the base of the reefs, creating a much lower pH environment than is currently found in the open ocean. These ‘natural’ laboratories are giving scientists a rare opportunity to examine what is already happening to corals dealing with lower pH levels predicted for the future.
One example is a coral reef system located among the volcanic islands of Papua New Guinea. Here, streams of gas bubbles rise up from the seafloor, lowering the pH of the overlying seawater. Similar low pH conditions are found at vent sites off Japan, freshwater seeps in Mexico, and upwelling areas in regions of the eastern tropical Pacific Ocean.
‘The coral reef system at the Papua New Guinea vent site is an algae-dominated one with few species of corals,’ says Barkley. ‘We see responses much like those shown in many lab experiments at some of the other naturally low pH coral reef sites as well, particularly lower calcium carbonate production. But we don’t see the same responses across all of the sites, especially not at the coral reefs in Palau Rock Islands. The coral communities there are thriving, except for higher rates of bioerosion.’
In collaboration with the Palau International Coral Reef Center, members of Cohen’s lab have been conducting fieldwork there since 2011. The research team collected water and coral skeletal core samples from eight sites across the Palau reef system, and deployed pH, light, salinity and flow sensors to characterize the seawater environment in which the corals grew. The research team also collected and analyzed data on the community composition as well.
The skeletal cores were scanned at the Computerized Scanning and Imaging Facility at WHOI. The Computerized Axial Tomography technology generates a 3-D image of the cores, revealing detailed information not visible to the naked eye, including coral growth rates, skeletal densities and the extent of bioerosion.
Using an automated program written in Matlab, the team used the 3-D images to quantify the proportion of the coral skeletons that had been eroded by organisms, and the severity of bioerosion of each coral. As the pH of the reef seawater drops, more frequent and severe bioerosion scars were revealed in the coral scans.
‘We see coral skeletons that are eaten up and have holes on the top and sides. The coral almost looks like Swiss cheese because of the volume that’s been removed,’ says Barkley.
Barkley and her colleagues found bioerosion rates in Palau corals increased eleven-fold as pH decreased from the barrier reefs to the Rock Island bays. When comparing those results to other low pH reef sites, a definite pattern emerged.
‘All of these naturally low pH sites that Hannah compared are different from one another in terms of physical setting, ecological connectivity, frequencies of variability and so on. What she discovered is that the only common and consistent response to -across all these sites is significantly increased bioerosion,’ says Cohen.
‘This paper illustrates the value of comprehensive field studies,’ adds David Garrison, program director in the National Science Foundation’s Division of Ocean Sciences, which funded the research. ‘Contrary to laboratory findings, it appears that the major effect of ocean acidification on Palau Rock Island corals is increased bioerosion rather than direct effects on coral species.’
The riddle of resilience
So how do Palau’s low pH reefs thrive despite significantly elevated levels of bioerosion? The researchers aren’t certain yet, but hope to be able to answer that question in future studies. They also don’t completely understand why conditions created by ocean acidification seem to favor bioeroding organisms. One theory is that skeletons grown under more acidic conditions are less dense making them easier for bioeroding organisms to penetrate coral skeletons. But that is not the case on Palau, Barkley says, ‘Because we don’t see a correlation between skeletal density and pH on Palau.’
A previous study published January 2015 in the journal Geology by Thomas DeCarlo, a member of Cohen’s lab and a co-author on this paper, showed that the influence of pH on bioerosion is exacerbated by high levels of nutrients. That finding implies that local management strategies, such as controlling runoff from land, can help to slow the impact of ocean acidification on coral reef decline. Increased runoff from areas of intense agriculture and coastal development often carries high levels of nutrients that will interact with decreasing pH to accelerate coral reef decline.
Though coral reefs cover less than one percent of the ocean, these diverse ecosystems are home to at least a quarter of all marine life. In addition to sustaining fisheries that feed hundreds of millions of people around the world, coral reefs protect thousands of acres of coastline from waves, storms, and tsunamis.
‘On the one hand, the results of this study are optimistic,’ Cohen says. ‘Even though many experiments and other studies of naturally low pH reefs show that ocean acidification negatively impacts calcium carbonate production, as well as coral diversity and cover, we are not seeing that on Palau. And that gives us hope that some coral reefs — even if it is a very small percentage — might be able to withstand future levels of ocean acidification. But there’s also a cautionary side, even for those coral communities able to maintain their diversity and growth as the oceans become more acidic, increased rates of bioerosion and dissolution seem inescapable.’
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Along with Barkley, Cohen, and DeCarlo, the team included Yimnang Golbuu of the Palau International Coral Reef Center, Victoria Starczak of WHOI, and Kathryn Shamberger of Texas A&M University.
Additional funding for this work was provided by The Dalio Foundation, Inc., The Tiffany & Co. Foundation, The Nature Conservancy, and the WHOI Access to the Sea Fund.
Those darn denier polyps out on those reefs. Don’t they know 97% of the other polyps in the more progressive reefs believe? They probably think the Earth is flat too.
Clearly climate scientists should start a communications initiative and a media blitz at once to whip those intractable corals into an orderly acknowledgement of the consensus.
/ sarc
I’m going diving! Maybe the reefs are therapeutic now!
Another therapeutic effect can be had by consuming carbon dioxide, carbonate ions, and bicarbonate ions along with a bit of scotch. I believe it is less risky than diving as well – at least in the short run. I find it useful after reading McKibben.
Since the beginning of the Industrial Revolution, ocean pH has fallen by 0.1 pH units
How do you know this? Are you simply basing it on atm CO2 concentration and Henry’s Law? If so, you’d also have to take buffering or some other feedback into account. This value certainly wasn’t measured, only estimated or assumed.
If you make loads of spurious claims, the chances are that one of them will turn out right by shear dumb luck.
So, what I find so incredible, is that the alarmists by shear dumb luck — have failed to find any claim that stands up.
Scottish Sceptic sez:
“So, what I find so incredible, is that the alarmists by shear dumb luck — have failed to find any claim that stands up.”
It is rather remarkable, innit?
LMAO!
““So, what I find so incredible, is that the alarmists by shear dumb luck — have failed to find any claim that stands up.””
It is because all of the memes are based on disaster looming and then spiraling out of control.
They completely fail to note the reality: Nature spins up disasters… small ones, large ones, and stupendously gigantic ones…on a regular basis.
What always happens next is that life immediately gets bust repairing the damage and restoring equilibrium.
Whether giant fires, volcanic eruptions (talk about a lot of acid all at once!), bolide impacts, glaciation, you name it…nature heals.
Twelve thousand years ago the oceans were two hundred feet lower and likely had a much altered chemistry. When all that ice melted, and sea levels rose…somehow all the coral kept up with the rapid rise, and changing ocean chemistry.
Because that is what life does.
Organisms like corals, that reproduce by tiny polyps released in vast quantities, ensure that adaptation will be rapid, and ecological niches will be quickly filled.
” ‘Surprisingly, in Palau where the pH is lowest, we see a coral community that hosts more species, and has greater coral cover than in the sites where pH is normal,’ says Anne Cohen, a co-author on the study and Barkley’s advisor at WHOI. ‘That’s not to say the coral community is thriving because of it, rather it is thriving despite the low pH, and we need to understand how.’ ”
Ms. Cohen, maybe pH, as long as it is in the alkaline range, doesn’t really matter that much to the coral community.
” The CO2 reacts with water molecules, lowering the ocean’s pH in a process known as ocean acidification. This process also removes carbonate ions”
Oh golly gee, if only there were trillions of tons of carbonate sediment just lying on the sea floor readily available to replace those carbonate ions….
‘That’s not to say the coral community is thriving because of it, rather it is thriving despite the low pH, and we need to understand how.’
I’m guessing if the coral was not thriving, the message would be ‘That’s not to say the coral community is ailing despite the low pH, rather it is ailing because of it, and we know who to blame.’
Fertilizer runoff is a pollutant and a problem in need of a better solution.
Human activity’s contribution to atmospheric CO2 is highly diffused by the time it comes in contact with the oceans, and is so miniscule that it probably has little effect on ocean chemistry. If it did add a significant amount of CO2 to the oceans, it would promote life due to the more available dissolved carbon. The life processes of ocean organisms convert dissolved carbon into skeletons. Their bodies use different chemistry than what is in the surrounding seawater. They wouldn’t due well in concentrated acid, sure. But the sheer volume of the oceans will, no doubt, prevent trace amounts of atmospheric gasses from converting the water into an acid bath.
I think we should also consider it a regional problem. The poison is the dose. While it can cause dead zones, ultimately these things feed the things we feed on. Same is true of oilspills.
But they banned phosphates from our dishwashing detergent based on absurd experiments of phosphate migration in SAND on Cape Cod, (where most all the MA Title V failures occurred in the 90’s). Phosphate is immediately fixed in normal soil. I have private sewage, do not live on Cape Cod and now use more water washing my dishes by hand or touching them up after the dishwater because of an EPA (or whoever) recommendation aimed to … save water. What I’m seeing is “knee-jerk science”, poorly researched, politically motivated and serving no practical improvement for people or the environment.
Fanatic efforts to save water by mandating toilet design rules in downtown San Francisco by the eco-enviro-extremist democrats there led to sewage and excrement blocking the main sewage lines there: The old flow toilets used adequate water-per-flush amounts to keep the pipes clean at modest underground slopes and adequate volumes to the sewage treatment plants. Mandating extreme low flush toilets in the city for all new toilets each time a building permit was issued – for any reason – led to “low” and stagnant water in the pipes.
So the smell of raw sewage backing up behind blocked pipes in modern San Francisco pollutes many neighborhoods with fumes and effluent coming up into toilets, back up vent pipes, and into open streets. Where it flows downhill in the curbs and gutters right back into the bay, into storm sewage drains, and into other houses.
“Let them smell toilet cakes.”
OMG
“Lethal Seas” program on PBS featuring Panelist Gretchen Hofmann
http://westcoastoah.org/lethal-seas-program-on-pbs-featuring-panelist-gretchen-hofmann/
Yep, in lab (and some field) experiments hydrochloric acid is used to decrease pH to the desired level. On the other hand on Palau there is only a slight decrease of bicarbonate (hydrogen carbonate) and increase of carbonic acid and dissolved carbon dioxide.
Now, excess Chlorine in seawater is a toxic substance, while neither carbonic acid nor carbon dioxide are toxic. Perhaps that’s what makes a difference, not pH alone.
Most alarmist don’t expect any role for evolution. (At the same time, they strongly oppose creationism.)
I believe some of the experiments raised pH by bubbling CO2 through the water. This is slightly better, but not much. Better would be to raise the CO2 concentration in the air above the surface, and see what it takes to raise the pH and that effect on biota.
‘This paper illustrates the value of comprehensive field studies,’
Duuuuuh! Perhaps they do not teach this anymore and just teach how to program models to get funding.
I wonder how many times the coral reefs have had to adapt to changing ocean pH levels over the past hundreds of millions of years? You don’t suppose, that – until mankind showed up – the pH levels remained constant? So, then, if the coral reefs have survived to the present day, then they must not be quite so fragile – and are more resilient, than we’d previously supposed?
Once again, scientists fail to credit animals with the ability to adapt to their environment, even though the evidence is all around us.
Adapt heck, these animals had to adapt to the low CO2 levels of the last few million years. Increased CO2 levels are just taking them back to what they originally evolved for.
‘That’s not to say the coral community is thriving because of it, rather it is thriving despite the low pH, and we need to understand how.’
That’s quite a claim for them to make, especially considering the fact that these corals first evolved when CO2 levels were much higher than the worst estimates for future CO2 increase.
Until fairly recently (compared to the age of these organisms) CO2 levels were well above where they are today.
@Bryan A
…the only true carbon pollution come out of the tail pipes of old diesel engines…
Actually, there’s a lot of carbon pollution on the photocopied pages of all the EPA reports….
.. and all those reams of IRS forms that only financial experts can fully understand.
There has been no ocean acidification and little global warming , soooooooooo why would coral reefs be having problems ???
‘The coral reef system at the Papua New Guinea vent site is an algae-dominated one with few species of corals,’
============
PNG from first hand experience has some of the finest corals in the world. Volcanic vents produce much more than CO, for example sulfur, which favors certain microorganisms over others.
Research of Dr. Roy E. Price
Ambitle Island (Papua New Guinea)
Distribution, speciation and bioavailability of arsenic in a shallow-water submarine hydrothermal system, Tutum Bay, Ambitle Island, PNG
Shallow-water hydrothermal vent systems can introduce large amounts of potentially toxic elements, such as arsenic (As), into coastal marine environments. The first step in understanding and describing the potential impact of these elements throughout hydrothermally influenced coastal ecosystems is to determine the element’s distribution and speciation, which in turn influences the availability of the toxin for biological uptake. Shallow submarine hot springs near Ambitle Island, Papua New Guinea, are discharging as much as 1.5 kg per day of arsenic directly into a coral-reef ecosystem.
Deep sea gold rush: World’s hydrothermal vent fields
By late 2013, Nautilus Minerals of Vancouver, Canada, plans to begin mining for copper and gold at a hydrothermal vent field known as Solwara 1. Under the United Nations Convention on the Law of the Sea, this lies in Papua New Guinea’s exclusive economic zone, but similarly valuable deposits may lie in international waters, where mining claims are regulated by the International Seabed Authority.
Seems suspiciously similar to Trenberth’s
“The fact is that we can’t account for the lack of warming at the moment and it is a travesty that we can’t.”
By the way it is “bioerosion” that produces that nice, white coral sand that builds up atolls.
If there is no bioerosion, no new coral sand is produced and those atolls will soon be washed away by the ocean.
Willis wrote an article a while back explaining about it and the parrot fish – http://wattsupwiththat.com/2013/06/13/why-the-parrotfish-should-be-the-national-bird/
Any day now people will start a mass migration fleeing Funafuti http://www.bom.gov.au/ntc/IDO70056/IDO70056SLI.pdf
For an excellent explanation of the ‘30%’ change see here
http://joannenova.com.au/2015/06/researchers-astonished-coral-reefs-thriving-in-a-more-acidic-ocean/#comment-1717918
bob prudhomme What are they doing to combat the CO2 bubbling up from the ocean floor and Volcanic CO2 ? sarcasm
Anne Cohen, a co-author on the study says, “That’s not to say the coral community is thriving because of it, rather it is thriving despite the low pH, and we need to understand how.’
Interesting comment. Had the team seen a coral community in decline and greatly stressed, do you think she would have said “That’s not to say the coral community is in decline because of it (CO2) … ” Hell no.
‘Ocean acidification’ is an emotive term; once the pH of sea water drops below 7, that term might have some relevance.
As they say in Sales 101, sell the emotion. Most lay persons associate “acid” with nasty things and then incorrectly extrapolate “acidification” nasty things are now going to happen. Mission accomplished by the BPC.
Doesn’t acidification come after neutral? A lower ph doesn’t mean acidified it means lower ph. If we pass neutral then we can start talking acid. until then go away.
People start complaining about income inequality when they earn less than their neighbour, not when they earn more than their neighbour.