AI Article Synopsis
- Human activities are drastically changing coastal marine ecosystems, leading to the replacement of diverse habitats like kelp forests and coral reefs with less valuable turf algal mats.
- Ocean acidification is favoring turf algae growth, creating conditions that lead to stabilizing feedback loops which can lock these degraded systems in place and hinder recovery.
- Understanding how these feedback mechanisms work is crucial for developing effective management strategies that protect coastal ecosystems and their benefits to human wellbeing.
Article Abstract
Human activities are rapidly changing the structure and function of coastal marine ecosystems. Large-scale replacement of kelp forests and coral reefs with turf algal mats is resulting in homogenous habitats that have less ecological and human value. Ocean acidification has strong potential to substantially favour turf algae growth, which led us to examine the mechanisms that stabilise turf algal states. Here we show that ocean acidification promotes turf algae over corals and macroalgae, mediating new habitat conditions that create stabilising feedback loops (altered physicochemical environment and microbial community, and an inhibition of recruitment) capable of locking turf systems in place. Such feedbacks help explain why degraded coastal habitats persist after being initially pushed past the tipping point by global and local anthropogenic stressors. An understanding of the mechanisms that stabilise degraded coastal habitats can be incorporated into adaptive management to better protect the contribution of coastal systems to human wellbeing.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7901039 | PMC |
| http://dx.doi.org/10.1038/s42003-021-01712-2 | DOI Listing |
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