Skeletal growth capacity as a measure of coral species and community resilience

Accretion and erosion of scleractinian (stony coral) carbonate skeletons determine whether a colony will increase or decrease in size with potential consequences for ecosystem processes, functions and services. The capacity for skeletal growth can be estimated by comparing a colony’s rate of calcifi...

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Bibliographic Details
Published in:Ecological Indicators
Main Author: William S. Fisher
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier 2022
Subjects:
Coral reef resilience
Stony coral growth
Stony coral condition
Stony coral erosion
Coral reef framework
Ecology
QH540-549.5
Ocean acidification
Online Access:https://doi.org/10.1016/j.ecolind.2022.109208
https://doaj.org/article/b31c6a7518a64974b30505aa27783232
Description
Summary:Accretion and erosion of scleractinian (stony coral) carbonate skeletons determine whether a colony will increase or decrease in size with potential consequences for ecosystem processes, functions and services. The capacity for skeletal growth can be estimated by comparing a colony’s rate of calcification with its rate of erosion. Calcification depends on the species-specific metabolic activity of living tissue, and erosion depends primarily on the availability and density of barren skeleton, those areas on the colony where polyps have died. Assessment of skeletal growth capacity requires data on calcification rates, erosion rates and both live and barren colony surface area. Rates of calcification and erosion are documented for many Caribbean species and others can be estimated from existing data. Three-dimensional surface area of colonies can be determined from data collected during demographic surveys, which identify species, measure dimensions, and estimate the proportion of live tissue on a colony. Data from demographic surveys conducted in the U.S. Virgin Islands are used to calculate the skeletal growth capacity (GC) as an indicator of coral species and community resilience. Scleractinia are the primary architects of coral reefs, and the gain or loss of skeletal framework is vitally important to reef ecosystem processes that lead to valued goods and services. Estimates of GC reflect stony coral resilience, which is the capacity to recover from disturbances by returning to previous physical and functional levels. GC can also provide insight to the effects of stressors such as ocean acidification, and can inform several management decisions, including restoration site selection and threatened species designation.

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