Guest Post by Willis Eschenbach
I love the coral reefs of the planet. In my childhood on a dusty cattle ranch in the Western US, I decorated my mental imaginarium of the world with images of unbelievably colored reefs below white sand beaches, with impossibly shaped fish and strange, brilliant plants. But when I finally first got to dive on the reefs, some forty years ago now, I found that my wildest imagination was only a pale, sickly phantasm compared to the real reef, the real beach, and the real sea life around it. It is a marvel of rioting color and exploding life where I have spent many happy hours, mesmerized.
Figure 1. Thousands of different types of living creatures together form the coral reef environment. SOURCE
Unfortunately, coral reefs are supposed to be threatened by increasing CO2. It’s supposed to make the various animals’ carbonate skeletons and shells dissolve, by decreasing the “pH” of the ocean (pH is a measure of relative alkalinity/acidity) and thus making the seas more neutral than they are today. Careful chemical calculations based on the complex carbonate chemistry of the ocean are said to prove that, no question. Aquarium tests are said to have shown it beyond a doubt, with statistically significant results. The claim has been repeated ad nauseam … and yet the reefs are thriving where they are not impacted by true threats like pollution and coral mining and curiously, the killing of parrotfish.
I have long held that the chemistry of the ocean was not ruled by the chemical energetics of the hundreds of various reversible reactions. That is the generally held view, that the ocean is ruled by chemistry. I hold the contrasting view, that the chemistry is not the last link in the chain. I say that the chemistry of the ocean is in turn ruled by life, and not the other way around as is the common assumption.
An early piece of evidence that shaped this view was when I found out that the pH of the water over a reef is not driven by chemistry, nor by the partial pressure of CO2 in the air. It is driven by the reef itself, which is a net producer of CO2. In other words, the biological products of the reef creatures themselves cause the water over the reef to move from more to less alkaline, often on a short time span. In one study the pH of the reef water changed by one full pH unit (1000% change) in 12 hours … and yet climate researchers breathlessly forecast dire consequences from much smaller pH changes than that spread out over a century, not 12 hours. From my experience with life in the ocean, and from my research, I am much more confident in the adaptability and tenacity of life than those researchers seem to be.
Figure 2. Cross section through a coral colony showing the living polyps, along with the carbonate skeleton built by the polyp. SOURCE
So I was interested to come across a research paper (paywalled, alas) with the unwieldy name of “Acclimation to ocean acidification during long-term CO2 exposure in the cold-water coral Lophelia pertusa.”
Abstract
Ocean acidity has increased by 30% since preindustrial times due to the uptake of anthropogenic CO2 and is projected to rise by another 120% before 2100 if CO2 emissions continue at current rates. Ocean acidification is expected to have wide-ranging impacts on marine life, including reduced growth and net erosion of coral reefs. Our present understanding of the impacts of ocean acidification on marine life, however, relies heavily on results from short-term CO2 perturbation studies.
Here we present results from the first long-term CO2 perturbation study on the dominant reef-building cold-water coral Lophelia pertusa and relate them to results from a short-term study to compare the effect of exposure time on the coral’s responses. Short-term (one week) high CO2 exposure resulted in a decline of calcification by 26-29% for a pH decrease of 0.1 units and net dissolution of calcium carbonate.
In contrast, L. pertusa was capable to acclimate to acidified conditions in long-term (six months) incubations, leading to even slightly enhanced rates of calcification. Net growth is sustained even in waters sub-saturated with respect to aragonite. Acclimation to seawater acidification did not cause a measurable increase in metabolic rates. This is the first evidence of successful acclimation in a coral species to ocean acidification, emphasizing the general need for long-term incubations in ocean acidification research. To conclude on the sensitivity of cold-water coral reefs to future ocean acidification further ecophysiological studies are necessary which should also encompass the role of food availability and rising temperatures.
I don’t have the full paper yet, but let me briefly discuss the abstract. The main message I see there is, the reef abides. The plants and animals of the ocean abide. The creatures that form carbonate shells and structures are tough and tenacious, they can do things we haven’t imagined. Their lifespan is often short enough to allow for evolution in human rather than geological time. They are able to change and modify, to adapt in response to changing water conditions. In addition, a healthy reef contains not just the dominant species in any given ecological niche, but a host of competing species. If it gets a bit warmer or colder, this alters the balance of the reef’s major simbionts, emphasizing a better-adapted competitor, and the reef keeps going. Even the “bleaching” events so feted by doomsayers are only minor occurrences in the reef’s geological history. Drill down, this has happened in the past. It is the extreme end of the scale of how the reef adapts to changing conditions. It gets rid of its symbionts wholesale, and starts over again. But the reef abides.
Next, a nitpick. The correct description for their claim is that the ocean waters have become more neutral. They have not become “more acidic” as the paper claims. They have moved towards neutrality. They have to pass through neutrality before they can start getting “more acidic”, and the ocean is a long ways from that.
Finally, I doubt greatly that we have anywhere near enough data to make the statement that “Ocean acidity has increased by 30% since preindustrial times”. See the second link above (repeated here http://wattsupwiththat.com/2010/06/19/the-electric-oceanic-acid-test/ ) for some of the very scarce real data.
I’ll update this if I can get a copy of the paywalled paper from my undersea connections …
[UPDATE—A denizen of the sub-aquatic world has tapped a trans-oceanic undersea fiber optic cable and sent me the paper, my thanks as always to Davey Jones. My comments follow.]
First, their statement about the so-called increase in ocean acidity is repeated in the body of the paper, but without citation … not good. They assert, without any evidence, that:
Presently the ocean takes up about 25 % of man-made CO2, which has led to a decrease in seawater pH of 0.1 units since 1800.
As mentioned above, that’s sketchy, observations of ocean pH are very scarce. Other than that, however, it is a fascinating paper. The experiment is very well described. They went down in a submersible and picked the coral branches, to assure good specimens and avoid damaging the reef. And also because it would be an awesome trip. They grew the specimens in their lab. Care to know what coral eat? Brine shrimp babies, that’s what, and not only that, they eat them alive, the heartless monsters.
The corals were fed twice a week with live Artemia franciscana (Premium, Sanders) nauplii and once a week with defrosted Cyclops (AD068, amtra Aquaristik) or ground fish flakes (TetraMarine Flakes, Tetra).
So. They did the short-term experiment using air with different amounts of CO2 above the water. The levels they chose were 509, 605, 856, and 981 µatmospheres (approximately, ppmv). This range starts with CO2 levels at about twice the pre-industrial values, and ends at around a thousand ppmv, a level which is extremely unlikely to be reached in this century.
In the short-term experiment (a week), the coral polyps fared very poorly. They failed to thrive, and at the higher levels, the corals’ carbonate skeletons were being eaten away by the high-CO2 water.
Then they did the long-term experiment, ramping up to the higher levels over a period of a few months. In this regard, there is a very revealing comment.
At the beginning, all CRS [the “closed recirculating systems” containing the coral] were supplied with ambient air with a pCO2 level of approx. 406 µatm. After taking water samples for TA [total alkalinity], DIC [dissolved inorganic carbon], and nutrients and measurements of the physicochemical water parameters (temperature, pH, salinity), sampling, the physicochemical parameters (salinity, pH, temperature) of each reactor were monitored by inserting a multi sensor device (Multi350i, WTW) into a small opening in the lid. During incubations, pH and pCO2 [partial pressure of CO2] can change differently in each bioreactor depending on rates of respiration and calcification of the enclosed coral branches. Therefore, the carbonate system parameters (pH, pCO2, ΩAr) and growth rates were calculated separately for each bioreactor.
In other words, what I said above—chemistry is being ruled by life, and not the other way around. The pH and the pCO2 are not simply functions of the amount of CO2 in the overlying air. They are functions of the reef and the reef life itself.
There were other interesting outcomes. In the short-term experiments, there is a statistically significant correlation between increasing CO2 and decreasing calcification rates (growth rates). As CO2 went up, growth went down, and coral skeletons were actually being eroded at the highest CO2 levels. This is a great example of how a statistically significant result can be entirely wrong because the experiment itself is conceptually flawed. The results are statistically significant … but meaningless.
Because in the long-term experiment (six months), the opposite occurred. The corals, once they had time to adapt to the change in pH and CO2 levels, did very well. The study reports:
Growth rates in the long-term experiment (LTE) did not follow the negative trend with increasing pCO2 observed in the short-term incubation. Instead, growth rate, which was comparable to that of the control treatment in the short-term experiment, stayed high at elevated CO2 levels. … Surprisingly, corals maintained in waters sub-saturated with respect to aragonite (CRS3, Tables 4 & 5) displayed the highest average Gr of 1.88 ± 1.34 × 10-2 % d-1. Positive net calcification in waters corrosive to aragonite was also confirmed by measurements of total alkalinity repeatedly performed over the course of the incubation, showing a continuous decrease during the long-term incubation in the highest CO2 treatment. There was no statistically significant relationship between average growth rates and pCO2 concentrations (Kruskal-Wallis ANOVA on ranks, H = 1.46, P = 0.482).
I want to expand on a couple of their statements. First, even when the chemistry predicted that the ocean waters would actively erode and dissolve the coral skeleton … it didn’t happen. In waters where it should have dissolved, it didn’t.
But the most important finding was the final one, which I can paraphrase as:
Coral growth rates are not related to CO2 levels.
It’s not even that CO2 doesn’t affect growth levels much. They’re not related at all. As the paper said,
There was no statistically significant relationship between average growth rates and pCO2 concentrations
Even the highest CO2 levels tested, far above anything in the coming century, couldn’t stop the corals from growing, heck, it didn’t even slow them down. In other words, life wins out once more, against all odds. Gotta love it.
w.
PS—for those interested in the carbonate chemistry of the ocean, there’s a great calculator here.
Excellent post Willis!
I do have one nitpick in addition to the one Jimmy covered: “pH is a measure of relative alkalinity/acidity”
While I agree that is the common use language, pH is technically a measure of the H+ ion in solution and “Alkalinity” is a measure of the amount of H+ ions that could be added to the solution without increasing the H+ ion concentration, basically, the relative ability of a solution to resist pH changes. A solution can have a high alkalinity and be acidic, but it cannot be both alkaline (pH greater than 7) and acidic (pH less than 7), unless you consider neutral to be both instead of neither. (ie: Alkalinity is not to alkaline what acidity is to acid.)
As for the use of the term “ocean acidification”, I too think its abhorrent! While it is technically accurate, it is almost certainly intentionally misleading to the public at large.
Sorry for the high nitpicky-ness quotient, just FWIW.
” the pH of the reef water changed by one full pH unit (100% change) in 12 hours …” Wouldn’t a full pH unit be a 1000% change?
The regular posts on this site are always interesting and the discussion, though often predictable, is equally stimulating. Keep in mind that predictable is not a criticism.
However, the greatest value to me is the utility of this, and several other sites, in making my life so much easier by identifying published literature of interest. Even if it is pay-walled, for those of us with direct access to a in-house science library, a simple cut, past, e-mail to the librarian (very special people), and there it is on my chair, often the same day, never longer than 2 or 3.
WUWT (Anthony) and the regular contributors (you know who you are) offers this as a great service!!! Thanks.
It is worth noting that the reefs at Eniwetok Atoll fully recovered from repeated thermonuclear detonations.
Do we know if oceans have more CO2 in them they the did 30 years ago.
Said differently does ocean water of the same temperature in the middle of the ocean say 100 feet below the surface have more CO2 in it.
And [seems obvious] can that CO2 be measured as accurately as CO2 in the air is measured.
If CO2 have risen, if CO2 in ocean can be measured as accurately as atmospheric air. Why
do measure CO2 on a volcanic mountain in Hawaii?
I have one huge problem with Willise’s article, and that is that, of course, we know it cannot be true. Lets look at that…
We know that there has been far more CO2 in the past.
We know that too much CO2 will kill all the coral, the science is settled.
Therefore the CO2 in the past killed all the coral.
Therefore there is no coral.
This must be some sort of giant, world wide lie, convincing us that coral exists, (my guess, it’s done by the tourist industry, they manufacture the stuff and paint it in bright colors.) You know, like the one that told us that we went to the moon, when everyone knows that it was all done in a hollywood studio.
Man, making all that fake coral must be a lot of work!
But seriously, I doubt that their experiment can be totally realistic because…
CO2 invigorates plant growth.
Plankton is a plant.
Invigorated plankton will suck CO2 out of the atmosphere, reducing it, rather than it staying steady as in this experiment.
(Too much of that will result in the too low amounts of CO2 we had 200 years ago).
Plankton is the start of the food chain, so the rest of the life will also be invigorated.
Coral is part of the food chain, so it is also likely to be invigorated.
Basically, to do the experiment right, they need to feed the coral more as CO2 goes up.
I haven’t read any of them. I avoid that site as it tends to be an agenda site that doesn’t take a discussion seriously that doesn’t validate it’s position.
By “modern corals” I mean Scleractinia. They appear in the fossil record in the middle Triassic. There is a 14 million year gap between them and any earlier corals. For about 14 million years there is no record of any skeletal corals but there may have been some soft-bodied corals that survived the Permian mass extinction and evolved into skeletal corals. All of the species that existed prior to the Permian extinction event disappear and do not reappear after.
Jeff D says (October 25, 2011 at 3:30 pm): “It also take close to 6 months for a system to be considered a mature tank. I also can not see how they could have set up control tanks. Every tank is unique.”
Perhaps at the end of the first experimental period the researchers could take the high-CO2 tanks gradually to lower levels, and lower-CO2 tanks to higher levels, as a control. Maybe they’re doing that as we write.
Brian H says:
October 25, 2011 at 3:11 pm
LIkely quite right. After millions of years the odds are that they’ve been there and done that. My point is that if they haven’t, a creature with a few year lifetime might pack thirty or forty generations into a hundred years, and that’s plenty for some survival of the way coolest …
w.
JDN says:
October 25, 2011 at 3:23 pm
Agreed. But the tests went beyond anything expected anytime soon.
w.
“DirkH says:
October 25, 2011 at 4:27 pm
Concentration of ions varies by about 30% when the pH changes by 0.3; the pH scale is the base 10 logarithm of the ion concentration.”
I usually agree with you, but this time I beg to differ. If the pH is 8.0, then the H+ concentration is 1.0 x 10^-8 mol/L. If this is increased by 30% then the H+ concentration becomes 1.3 x 10^-8 mol/L. The log of this number is 7.886, so the change of pH is only a decrease of 0.114.
I DO agree with:
“MaineIdea says:
October 25, 2011 at 4:43 pm
” the pH of the reef water changed by one full pH unit (100% change) in 12 hours …” Wouldn’t a full pH unit be a 1000% change?”
Werner Brozek (retired science teacher)
So basically, skeletal corals evolved twice on Earth and both times were when CO2 concentrations were much higher than today. While I do not necessarily place perfect confidence in CO2 proxies, I have enough general confidence to say that CO2 levels were much higher in the past when biodiversity was much greater than it is today. It doesn’t matter if they were 4x or 6x higher, just that they were significantly higher.
All of the CO2 we add to the atmosphere from burning fossil fuel was CO2 that was removed from the atmosphere. In other words, we are simply putting it back. It would eventually be put back anyway as crust is recycled. A volcano erupting through a major oil field would put a lot of it back in a hurry and it probably has at times in the past.
CO2 is constantly taken out of the atmosphere so over time its concentration drops. It is fairly obvious that over millions of years the amount of CO2 decreases in the atmosphere. If it didn’t gymnosperms would still be the dominant tree species on Earth instead of angiosperms. Our burning of fossil fuel gradually turns the atmospheric concentration of CO2 back to what it was in earlier times. In many ways we are giving many species a new lease on life. CO2 depletion has probably been giving many species a difficult time (Araucaria, for example) and taking some of this stored CO2 and releasing it back into the atmosphere is quite likely making things better for more species than it is making things worse for.
jae says:
October 25, 2011 at 4:12 pm
It’s just obfuscation, Jae. They claim, without citation or attribution, that the pH decreased by 0.1.
Since pH is a logarithmic scale, an increment of 0.1 is about a 26% increase, which they’ve rounded up to 30%. And curiously, a decrement of 0.1 is only a 20% decrease, because you’re starting with the larger number. So their 30% is a rounded version of 26%, which in turn is an error for 20% … in a system which is measured logarithmically for a good reason—because percentages don’t mean much when we’re speaking of pH.
In any case, that’s my explanation.
w.
Willis,
Nice post.
You are not the only one that has observed that mere chemistry doesn’t dictate sea water buffering capacity, and I say this as a chemist.
I’ve sparred a time or two in the blogosphere about this, and people who claim supreme accuracy for ocean pH measurement often struggle to supply me with a reference that is ironclad. Among those that were offered up was this one:
http://www.jodc.go.jp/info/ioc_doc/Experts/120608eo.pdf#8**
In Annex III, you can see a detailed discussion of the inability to match results between “real” seawater and “artificial” seawater. It seems the buffering chemistry of “real” seawater is difficult to replicate. My simple mind tends to believe that there may very well be some “biological” buffering going on that is not accounted for in the very careful attempts to develop accurate ocean pH measuring techniques.
Anyway, a couple of other points:
You wrote:
As MaineIdea alludes to, since the pH scale is a log function, one unit is a factor of ten, or 1000% (I suppose there are some purists that say a ten-fold increase is an increase of 900%, but I’ll leave that one go for now.)
Jeff D says: October 25, 2011 at 3:30 pm
Again, pH is a log scale (actually, negative log).
http://en.wikipedia.org/wiki/PH
It is estimated that the ocean pH has dropped ~0.1 pH unit since the 1800s (based on calculations using carbonate/bicarbonate equilibrium constants and the increase in atmospheric CO2).
So…
pH 8.2; hydrogen ion concentration = 10^-8.2 = 6.3e-9 molar
pH 8.1: hydrogen ion concentration = 10^-8.1 = 7.9e-9 molar
This is an increase of about 25-30% in hydrogen ion content.
BTW, regarding ocean “acidification”, your tax dollars at work (go to ~5:00 min).
Excellent. Thank you Mr. Eschenbach
Don K says:
October 25, 2011 at 4:30 pm
Technically, yes. But as an actual description that conveys a meaning, no. The ocean is alkaline. Life doesn’t do well with alkaline. That’s one reason why fish are covered in mucus, and why they used to put lye in mass graves.
So in terms of the words as they affect life, the problem is that generally for living things, movement towards neutral is a good thing, regardless of whether it’s heading more or less acidic. And moving away from neutral is a bad thing, again whether it’s more or less acidic.
As a result, the scientifically correct term “acidifying” conveys entirely the wrong meaning. The impression is that we are moving towards a bad state, acidity. The equally accurate terms, “becoming more neutral”, or “moving towards neutrality”, convey the actual meaning, which is that we are moving towards a good or at least a neutral state.
“More neutral” is likely not to be a bad thing for the ocean. “Acidic” would be a dangerous state.
So while you guys are 100% correct, this is one time where scientific jargon is dangerously misleading the public. As such, I fight for an equally correct, but more … ahem … neutral terminology.
My thanks to both of you,
w.
Some folks have said that thirty or forty generations is far to short for the polyps to evolve to meet new conditions. Let me offer this, from Science magazine article “Rapid Evolution of Reproductive Isolation in the Wild: Evidence from Introduced Salmon”
There’s many more articles on the subject, but that should lay to rest the idea that thirty or forty generations is not enough to see evolution at work.
w.
MaineIdea says:
October 25, 2011 at 4:43 pm
Could be. Each unit is ten times as large, so yes, that would be right … highlights the foolishness of using percentages in a logarithmic system. I’ll change it.
w.
Philip Finck says:
October 25, 2011 at 4:49 pm
You’re welcome, Philip, and that’s why my articles are cited including the paywalled stuff.
w.
Gary Hladik says:
October 25, 2011 at 5:19 pm
Oh, ye of little faith. The short term experiment.
and the long-term experiment
w.
Just to give you something else to think about, the vast majority of buffering systems have very strong temperature coefficients. Using mulitpul buffers things get very complciated very quickly, so the only thing to do is measure it.
Here is a goody from 1969.
EFFECT OF TEMPERATURE ON THE pH OF SEAWATER
Joris M. Gieskes
“The temperature coefficient of the pH of seawater, calculated from existing data on the
carbonate system in seawater, is confirmed experimentally as +0.0114 pH units per degree
Celsius at 1 atm pressure.”
http://www.aslo.org/lo/toc/vol_14/issue_5/0679.pdf
Hmm. I wonder what the rate of evolution is for reef critters?
Its probably very high.
http://www.cs.unc.edu/~plaisted/ce/rates.html
Well, as a chemist (although only a specialist in a very distant area), I would be very surprised if the CO2 levels in the air can make ANY significant difference to the pH of the oceans, considering the enormous buffering that is available in those oceans. Like Willis says sometimes, my BS meter is pegged, and I want to see some actual data, not more models and silly speculation. DATA.
In fact, I think Josh should do a cartoon about this nonsense: maybe a cute little polyp battling a great big CO2 molecule…OK, corny.
One certain thin in my mind is that the pseudoscientific “climate science” guys/gals are making their science (and maybe all science) look stupid!
Noble Cause Corruption, indeed! But also a big helping of simple “Government Grant Corruption,” very similar to what Eisenhower warned about.
crosspatch says:
October 25, 2011 at 5:16 pm
I have not read all the comments on the Real Climate post
I haven’t read any of them. I avoid that site as it tends to be an agenda site that doesn’t take a discussion seriously that doesn’t validate it’s position.
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I don’t disagree, but the post I cited is more speculative than most climate crap and seems to contain a pretty good summary of a lot of recently worked out puzzling data about Late Cretaceous and Early Tertiary phenomena — including a sudden, short, sea level drop (along the New Jersey shore) in the Upper Cretaceous that can only be explained by massive continental ice accumulations. At least if you are an adherent to “Climate science.” I really think that you might find it worth perusing.
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By “modern corals” I mean Scleractinia. They appear in the fossil record in the middle Triassic. There is a 14 million year gap between them and any earlier corals. For about 14 million years there is no record of any skeletal corals but there may have been some soft-bodied corals that survived the Permian mass extinction and evolved into skeletal corals. All of the species that existed prior to the Permian extinction event disappear and do not reappear after.
===============
The fossil record is REALLY full of holes. Witness the lack of Coelacanth fish between the Cretaceous and one turning up alive in South Africa 70 years ago. And more — different genus — in an Indonesian fish market a few years ago. These are BIG fish BTW not baitfish that one might overlook
The Permian-Triassic extinction event was the most severe that we know of, and the shorelines and shelves of the world were unusually limited because of the continents having blundered together to form the Pangaean supercontinent. If you are not familiar with the Christopher Scotese’s Paleomap Project, it is worth checking out http://www.scotese.com/climate.htm
Recolonization seems plausible. A possible source is deep water coral reefs. These reefs are poorly known even today. They are apparently quite extensive and the corals that build them are quite cold tolerant. Presumably the deep ocean basins have always been near freezing. The ocean basin environments where deep water corals are found are rarely preserved and pushed up onto the continents, so we don’t know how long the deep water corals have been around.
Thus the coccoliths and corals were taken to high levels of CO2 in too short time. If given enough time (even a few months is extremely fast in geological times), they just thrive as long before. Nice to know that… Thanks for the new knowledge!
The same thing happens with human beings. If you fly into Everest base camp and start climbing you have a much higher chance of dying of altitude sickness than if you walk in over a 2-4 week period before you start climbing.