Bubbling sea signals severe coral damage this century

Dobu Island in Papua New Guinea has active underwater fumaroles (Jennifer Marohasy posted on it a few years back) that seep high concentrations of CO2 into the environment, in turn acidifying the surrounding ocean. These vents have been active for at least 50 years: according to village elders  these seeps have existed at that location throughout their life (the local traditional site name “Illi Illi Bua Bua” translates to “Blowing Bubbles”).

Katherina Fabricius and a collaboration of scientists have published an amazing article in the journal Nature Climate Change looking at a gradient across these seeps and the impacts on coral reef ecosystems. The results are striking:

Seascapes at a, control site (‘low pCO2’: pH~8.1), b, moderate seeps (‘high pCO2’: pH 7.8–8.0), and c, the most intense vents (pH<7.7), showing progressive loss of diversity and structural complexity with increasing pCO2. d, Map of the main seep site along the western shore of Upa-Upasina (marked as grey; map: Supplementary Fig. S1). Colour contours indicate seawater pH, and the letters indicate the approximate locations of seascapes as shown in a–c.

“The implications of the observed ecological changes for the future of coral reefs are severe. The decline in structurally complex framework-forming corals at lowered pH is likely to reduce habitat availability and quality for juvenile fish and many invertebrates. The low coral juvenile densities (including those of Porites) probably slows coral recovery after disturbance, suggesting reduced community resilience. The loss of crustose coralline algae that serve as settlement substratum for coral larvae probably impedes larval recruitment, and the doubling of non-calcareous macroalgae reduces the available space for larvae to settle. Susceptibility to storm breakage would also increase, if internal macrobioeroder densities in massive Porites are indicative of borer densities in other coral taxa and reef substrata.”

Bearing in mind these caveats, our data nevertheless suggest that tropical coral reefs with high coral cover can still exist at seawater pH of 7.8 (750 ppm pCO2), albeit with severe losses in biodiversity, structural complexity and resilience. As pH declines from 8.1 to 7.8 units, the loss of the stenotopic fast-growing structurally complex corals progressively shifts reef communities to those dominated by slow-growing, long-lived and structurally simple eurytopic massive Porites (Fig. 1a,b).

Reef development ceases at 7.7 pH units (980 ppm pCO2), suggesting these values are terminal thresholds for any form of coral reef development.  T

The big question that remains is how elevated sea temperatures will interact with the effects of acidification.  So far, it doesn’t look hopeful (Anthony et al. 2008). More from the BBC and Sciencedaily. Unsurprisingly, no word from Andrew Bolt, Anthony Watts or Jennifer Marohasy.

5 thoughts on “Bubbling sea signals severe coral damage this century

  1. could you please point me to the papers that show that the fresh water lakes of the world are becoming less alkaline due to atmospheric CO2.

    Here’s information regarding 139,000 submarine volcanoes causing the ocean to become less alkaline and where all the increase in CO2 is actually coming from.

    http://carbon-budget.geologist-1011.net/

  2. Pingback: This weather is killing my spirit (06/02) | Nicholas Fabina

  3. Your link assumes temperature change causes change in pH.

    Regards the volcanoes – here’s the full paper – please address the science without attacking the messenger. It’s all fully referenced.

    http://www.au.agwscam.com/pdf/Volcanic%20Carbon%20Dioxide.pdf

    Currently the CSIRO and BoM quote Gerlach 1991 as their source of volcanic CO2 – may I remind you that it’s now 2011 and many papers, as the ones referenced in the above paper, have changed that view and have shown Gerlach 1991 to be an unreliable source of information regarding volcanic contribution to the current CO2 levels.

    • No it doesn’t. Read the article a little more closely. The acidification effect comes from the increased partial pressure of carbon dioxide in the atmosphere.

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