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Could artificial ocean alkalinization protect tropical coral ecosystems from ocean acidification?
Artificial ocean alkalinization (AOA) is investigated as a method to mitigate local ocean acidification and protect tropical coral ecosystems during a 21st century high CO _2 emission scenario. Employing an Earth system model of intermediate complexity, our implementation of AOA in the Great Barrier Reef, Caribbean Sea and South China Sea regions, shows that alkalinization has the potential to counteract expected 21st century local acidification in regard to both oceanic surface aragonite saturation Ω and surface pCO _2 . Beyond preventing local acidification, regional AOA, however, results in locally elevated aragonite oversaturation and pCO _2 decline. A notable consequence of stopping regional AOA is a rapid shift back to the acidified conditions of the target regions. We conclude that AOA may be a method that could help to keep regional coral ecosystems within saturation states and pCO _2 values close to present-day values even in a high-emission scenario and thereby might ‘buy some time’ against the ocean acidification threat, even though regional AOA does not significantly mitigate the warming threat.
Could artificial ocean alkalinization protect tropical coral ecosystems from ocean acidification?
Artificial ocean alkalinization (AOA) is investigated as a method to mitigate local ocean acidification and protect tropical coral ecosystems during a 21st century high CO _2 emission scenario. Employing an Earth system model of intermediate complexity, our implementation of AOA in the Great Barrier Reef, Caribbean Sea and South China Sea regions, shows that alkalinization has the potential to counteract expected 21st century local acidification in regard to both oceanic surface aragonite saturation Ω and surface pCO _2 . Beyond preventing local acidification, regional AOA, however, results in locally elevated aragonite oversaturation and pCO _2 decline. A notable consequence of stopping regional AOA is a rapid shift back to the acidified conditions of the target regions. We conclude that AOA may be a method that could help to keep regional coral ecosystems within saturation states and pCO _2 values close to present-day values even in a high-emission scenario and thereby might ‘buy some time’ against the ocean acidification threat, even though regional AOA does not significantly mitigate the warming threat.
Could artificial ocean alkalinization protect tropical coral ecosystems from ocean acidification?
Ellias Y Feng (冯玉铭) (author) / David P Keller (author) / Wolfgang Koeve (author) / Andreas Oschlies (author)
2016
Article (Journal)
Electronic Resource
Unknown
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