The contribution of corals to reef structural complexity in Kāne‘ohe Bay

Miller, Spencer; Yadav, Shreya; Madin, Joshua S.

doi:10.1007/s00338-021-02190-y

Cited by 7 publications

(6 citation statements)

References 30 publications

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“…S8 and S9). This is consistent with a recent study in Oahu, Hawaii where the associations between structural complexity and specific coral species were found to be closely tied to species morphology 59 . Millepora , on the other hand, exhibited some variability in both sizes and morphologies, but they lacked small colonies (i.e., 0–5 cm in size, Fig S5).…”

Section: Discussionsupporting

confidence: 93%

Prediction of habitat complexity using a trait-based approach on coral reefs in Guam

Ferreira

Burns

Pascoe

et al. 2023

Sci Rep

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Scleractinian corals are primary contributors to the structural complexity of coral reef ecosystems. The structure derived from their carbonate skeletons underpins the biodiversity and myriad of ecosystem services provided by coral reefs. This study used a trait-based approach to provide new insights into the relationships between habitat complexity and coral morphology. Three-Dimensional (3D) photogrammetry techniques were used to survey 208 study plots on the island of Guam, from which structural complexity metrics were derived and physical traits of corals were quantified. Three traits at the individual colony level (e.g., morphology, size, and genera) and two site-level environmental characteristics (e.g., wave exposure and substratum-habitat type) were examined. Standard taxonomy-based metrics were also included at the reef-plot level (e.g., coral abundance, richness, and diversity). Different traits disproportionately contributed to 3D metrics of habitat complexity. Larger colonies with a columnar morphology have the highest contribution to surface complexity, slope, and vector ruggedness measure, whereas branching and encrusting columnar colonies have the highest contribution to planform and profile curvature. These results highlight the importance of considering colony morphology and size in addition to conventional taxonomic metrics for the understanding and monitoring reef structural complexity. The approach presented here provides a framework for studies in other locations to predict the trajectory of reefs under changing environmental conditions.

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Section: Discussionsupporting

confidence: 93%

Prediction of habitat complexity using a trait-based approach on coral reefs in Guam

Ferreira

Burns

Pascoe

et al. 2023

Sci Rep

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“…For example, rugosity indices on study reefs (range: 1.0–2.2) agreed well with those reported by Karp et al (2018), Margiotta et al (2016), and Rodney and Paynter (2006), who measured linear rugosity indices between 1.2 and 3.0 on restored and relic oyster reefs. On the other hand, the intertidal oyster reefs investigated in the current study were markedly different than corals reefs, with prior studies reporting higher rugosity indices (Knudby & LeDrew 2007: 1–2.25; Burns et al 2015: 1.5; Yanovski et al 2017: 2.22; Carlot et al 2020: 2–3.75) and lower fractal dimensions (Zawada et al 2010: 2–2.5; Leon et al 2015: 2.2–2.6; Miller et al 2021: 2–2.5) for corals in comparison to oysters (

\overset{true¯}{R}

= 1.2–1.5;

\overset{true¯}{D}

= 2.67–2.74). Differences in roughness characteristics between corals and oysters may be due, at least in part, to differences in reef growth and development.…”

Section: Discussionmentioning

confidence: 80%

“…manual measurements of other natural marine canopies, including coral reefs (Knudby & LeDrew 2007;Leon et al 2015;Miller et al 2021), mussel beds (Commito & Rusignuolo 2000;Lim et al 2020), and oyster reefs (Margiotta et al 2016;Karp et al 2018). Although direct comparisons are complicated by variable measurement techniques, which can have significant effects on inferred surface complexity (Knudby & LeDrew 2007;Yanovski et al 2017), it is still useful to place the results of this study in the broader context of marine canopy literature.…”

Section: Roughness Characteristics Of Intertidal Oyster Reefmentioning

confidence: 99%

Characterizing canopy complexity of natural and restored intertidal oyster reefs (Crassostrea virginica) with a novel laser‐scanning method

Cannon

Kibler

Taye

et al. 2023

Restoration Ecology

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The structural complexity of oyster reef canopy plays a major role in promoting biodiversity, balancing the sediment budget, and modulating hydrodynamics in estuarine systems. Although oyster canopy structure is both spatially and temporally heterogeneous, oyster canopies are generally characterized using simple first‐order quantities, like oyster density, which may lack the ability to sufficiently parameterize reef roughness. In this study, a novel laser‐scan approach was used to map the surface of intact reference and restored reefs (restoration age: 1–4 years) during low tide, when the oyster canopy was fully exposed. Measurements were used to estimate hydrodynamically relevant roughness characteristics over the entire reef surface (>140 m2; 0.50 m resolution), providing estimates of the canopy height (hc), standard deviation (), rugosity index (R), and fractal dimension (D). Average canopy heights ranged from 3.6 to 4.9 cm, with canopy height standard deviations between 1.4 and 2.0 cm. Mean rugosity indices and fractal dimensions were relatively low on the youngest (1 year) restored reef (R = 1.28; D = 2.67), with substantial increases observed for more mature reef canopies (4 years: R = 1.56; D = 2.71). Structural complexity was consistently greater on reef margins than in reef interiors. Increases in complexity were linked to restoration age, with older reefs exhibiting more complex oyster canopies. The highest fractal dimension was observed on the intact reference reef, highlighting the importance of sustained reef growth for maintaining higher‐order structural complexity. Results provide spatially explicit surface roughness characterizations for healthy, intertidal oyster reefs, with applications in both restoration science and natural and nature‐based feature design.

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“…Fractal dimension and rugosity capture different elements of complexity on a reef and might work in asynchronous ways to affect processes like bleaching and mortality (Torres-Pulliza et al, 2020). While coral diversity in Kāne‘ohe Bay is low, species exist in a range of morphotypes and contribute differently to overall reef structure (Miller et al, 2021). While we did not detect changes in the 3D complexity of reefs one year post-bleaching, further monitoring will provide insight into how reef-scale R and D change as corals of different species grow, recover, or die.…”

Section: Discussionmentioning

confidence: 99%

Fine-scale variability in coral bleaching and mortality during a marine heatwave

Yadav

Roach

McWilliam

et al. 2022

Preprint

Self Cite

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Coral bleaching and mortality can show significant spatial and taxonomic heterogeneity at local scales, highlighting the need to understand the fine-scale drivers and impacts of thermal stress. In this study, we used structure-from-motion photogrammetry to track coral bleaching, mortality, and changes in community composition during the 2019 marine heatwave in Kāneʻohe Bay, Hawaiʻi. We surveyed 30 shallow reef patches every 3 weeks for the duration of the bleaching event (August-December) and one year after, resulting in a total of 210 large-area, high-resolution photomosaics that enabled us to follow the fate of thousands of coral colonies through time. We also measured environmental variables such as temperature, sedimentation, depth, and wave velocity at each of these sites, and extracted estimates of habitat complexity (rugosity R and fractal dimension D) from digital elevation models to better understand their effects on patterns of bleaching and mortality. We found that up to 80% of corals experienced moderate to severe bleaching in this period, with peak bleaching occurring in October when heat stress (DHW) reached its maximum. Mortality continued to accumulate as bleaching levels dropped, driving large declines in more heat-susceptible species (77% loss of Pocillopora cover) and moderate declines in heat-tolerant species (19% and 23% for Porites compressa and Montipora capitata, respectively). Declines in live coral were accompanied by a rapid increase in algal cover across the survey sites. Spatial differences in bleaching were significantly linked to habitat complexity and coral species composition, with reefs that were dominated by Pocillopora experiencing the most severe bleaching. Mortality was also influenced by species composition, fractal dimension, and site-level differences in thermal stress. Our results show that spatial heterogeneity in the impacts of bleaching are driven by a mix of environmental variation, habitat complexity, and differences in assemblage composition.

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The contribution of corals to reef structural complexity in Kāne‘ohe Bay

Cited by 7 publications

References 30 publications

Prediction of habitat complexity using a trait-based approach on coral reefs in Guam

Prediction of habitat complexity using a trait-based approach on coral reefs in Guam

Characterizing canopy complexity of natural and restored intertidal oyster reefs (Crassostrea virginica) with a novel laser‐scanning method

Fine-scale variability in coral bleaching and mortality during a marine heatwave

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