Rising carbon dioxide levels in our atmosphere are changing Earth’s climate at an unprecedented rate. Not only is our planet getting warmer on average—in the oceans, a chemical reaction spurred by dissolved CO2 is altering water chemistry, causing a decrease in pH. This effect of climate change, called ocean acidification, can dissolve the calcium carbonate foundations of coral reefs and other calcifying organisms, making it impossible to build and maintain healthy reefs. Luckily, recent studies on how corals react to lower pHs has given scientists hope that they may be more resilient than previously thought. However, to truly understand how reefs will respond to climate change, we have to look at more than just corals.
Reefs are complex ecosystems, the bases of which are comprised of so much more than corals. There are other species which act as calcifiers, adding to the carbonate foundation (such as crustose coralline algae). The contribution of these non-coral species to reef growth, called secondary accretion, helps shape the surface and guide the settlement of larval corals. There are also species that eat away at the reef, including many worms and sponges. These bioeroders can weaken reef structures until they crumble apart. Whether a reef grows or shrinks over time depends on the interplay between its corals, other reef-builders, and the burrowing organisms which eat their way through the reef’s carbonate foundation.
The corals have received a lot of scientific attention, with many laboratories around the world conducting field and lab experiments in an attempt to predict how these essential species will react to the higher temperatures and the altered seawater chemistry that will come with our changing climate. Relatively less attention has been paid to the other species that also determining the size and shape of the reef—in part because such studies are harder to design. After all, there could be hundreds of species on a reef contributing to secondary accretion or bioerosion. While it’s somewhat simple to take a coral into a lab tank and monitor changes as you tinker with water parameters, it’s impossible to do the same to a whole reef at once.
So instead, Nyssa Silbiger and her colleagues got creative. She precisely cut calcium carbonate blocks from the skeletons of dead Porites corals and placed them along a a natural environmental gradient in Kāne‘ohe Bay, O‘ahu, Hawai‘i, which varied in depth, temperature, nutrients, and pH. For a year, she let the organisms in the area do as they pleased. Encrusting organisms added to the blocks, while boring species cut through them. Then, she removed the blocks and determined how the environmental variables related to the block’s final size and shape.
Previous studies measured discrepancies in weight of similar blocks to get a vague understanding of change, but Silbiger wanted something more precise. To get a detailed picture, Silbiger and her team repurposed a technology designed for medical uses called microcomputed tomography, or μCT. If you’ve ever gotten a “cat” scan, then you’ve essentially experienced the same imaging technology; CT technologies allow for the examination of objects from the inside out. A CT scan of your head allows doctors to look for brain injuries by creating a three dimensional version of your brain and skull. Similarly, Silbiger and her colleagues were able to use μCT to generate three-dimensional images of the blocks before and after a year in the field.
The results, published this month in PLoS ONE, connected temperature and pH to alterations of the blocks. Silbiger and her colleagues found that accretion and erosion responded differently to the various environmental variables, with erosion in particular much more strongly linked to seawater acidity than anyone had previously seen. Such differences are important to note for scientists seeking to predict how reefs will respond to future changes. “Models predicting the impact of climate change on coral reefs often lump accretion and erosion processes together”, said Silbiger, “but the fact that we found different drivers means that we need to think more deeply about the predictive models we’re using.”
In addition to the findings, this study was a test of the use of µCT for studying reef growth and shrinkage—a test which µCT passed with flying colors, paving the way for future studies. “We are able to assess the addition or removal of calcium carbonate at a resolution of 100 micrometers—approximately the thickness of a human hair,” said Silbiger. “There is so much that we can learn about coral reefs using µCT scans. My colleagues and I are mining all the information we can from this exciting technology.”
But more importantly, the findings underscore just how vulnerable our planet’s reefs are to our changing climate. “The results of our study are sobering because it seems that even if corals can adapt, acclimatize or withstand changing ocean pH, bioerosion of the reef framework will still continue to increase,” Silbiger said.
Still, she’s optimistic about the future. “I think there’s a lot more to learn before we can say that reefs are going to disappear,” Silbiger said.
Citation: Silbiger NJ, Guadayol Ò, Thomas FIM, Donahue MJ (2016). A Novel μCT Analysis Reveals Different Responses of Bioerosion and Secondary Accretion to Environmental Variability. PLoS ONE 11(4): e0153058. doi:10.1371/journal.pone.0153058
Reversing ocean acidification and Klimate Kaos on a planetary scale merely requires disposal of two industrial waste streams using free energy. The Southern Sea is unproductive outside the Drake Passage and Scotia Sea. Absence of nano-nutrient iron and fertilizer wastes 18+-hr summer sun. Oceans acidify as more CO_2 dissolves. Prime the copepod CO2 pump big time where ocean never Klimate Kaos warms. DOI: 10.1007/s00227-010-1591-5; DOI:10.1016/j.marchem.2012.05.002; DOI: 10.1016/S0924-7963(97)00081-X
Bayer process bauxite to pure alumina produces 77 million tons/year of “red mud,” micronized iron oxide in pH 13 water. North Carolina produces 40 million gallons/day of liquid hog waste. Erect spray towers (wind power generators) along Macquarie Island’s southeast coast. The Furious 50s and the Antarctic Circumpolar Current will blow and row a billion gallons/year each of red mud and liquid hog manure east. Phytoplankton, zooplankton (copepods being dominant), krill,then fish will gorge. Feed the world.
Sequester carbon big time as oceanic feces sink and pelagic to demersal zone copepod metabolism. Ocean pH rises. Two huge waste lagoon storage issues vanish. Spraying 10 billion gallons/year of each is sustainable. Mean Antarctic Circumpolar Current transport is (100 -150)×10^6 metric tonnes/second, 26 – 40 billion gallons/sec. 10 billion gallons/year added is trace fertilization leveraging massive photosynthesis boosts, certainly from the iron. If Klimate Kaos then disappears, ban the empirical solution to restore the Carbon Tax on Everything and Carbon Credit arbitrage.
http://en.wikipedia.org/wiki/Ajka_alumina_plant_accident
http://en.wikipedia.org/wiki/Red_mud
http://www.elonpendulum.com/2014/04/north-carolina-hog-waste-disposal/
http://oceancurrents.rsmas.miami.edu/southern/antarctic-cp.html
http://www.clemson.edu/extension/livestock/camm/camm_files/swine/sch3a_03.pdf
“Swine manure contains all 13 of the essential plant nutrients that are used by plants”
Solving so-called Klimate Kaos is a quantum leap easier than actually removing a tax, placed by its primary beneficiaries 🙂
They are catching salmon and trout in the formerly dank Chicago and Thames Rivers, but Income Tax, a ‘temporary’ imposition to finance war expenditures is still with us, and growing exponentially, a couple hundred years later.
Once imposed, taxes are more virulent, than all known pathogens combined 🙂 Carbon taxes will remain forever!
“Environmental” taxes especially, are disguised as beneficial, not prohibitive, in such a way as to make a population of sheep, actually DEMAND them!