Dynamics of carbonate sediment production by Halimeda: implications for reef carbonate budgets

Reef carbonate production and sediment generation are key processes for coral reef development and shoreline protection. The calcified green alga Halimeda is a major contributor of calcareous sediments, but rates of production and herbivory upon Halimeda are driven by biotic and environmental factors. Consequently, estimating rates of calcium carbonate (CaCO3) production and transformation into sediment requires the integration of Halimeda gains and losses across habitats and seasons, which is rarely considered in carbonate budgets. Using seasonal rates of recruitment, growth, senescence and herbivory derived from observations and manipulative experiments, we developed an individual-based model to quantify the annual cycle of Halimeda carbonate and sediment production at Heron Island, Great Barrier Reef. Halimeda population dynamics were simulated both within and outside branching Acropora canopies, which provide refuge from herbivory. Shelter from herbivory allowed larger Halimeda thalli to grow, leading to higher rates of carbonate accumulation (3.9 and 0.9 kg CaCO3 m-2 yr-1 within and outside Acropora canopies, respectively) and sediment production (2.5 versus 1.0 kg CaCO3 m-2 yr-1, respectively). Overall, 37% of the annual carbonate production was transformed into sediments through senescence (84%) and fish herbivory (16%), with important variations among seasons and habitats. Our model underlines that algal rates of carbonate production are likely to be underestimated if herbivory is not integrated into the carbonate budget, and reveals an important indirect pathway by which structurally complex coral habitats contribute to reef carbonate budgets, suggesting that coral losses due to climate change may lead to further declines in reef sediment production.

Download Full-text

Temperate carbonate cycling and water mass properties from intertidal to bathyal depths (Azores, N-Atlantic)

Biogeosciences Discussions ◽

10.5194/bgd-7-3297-2010 ◽

2010 ◽

Vol 7 (3) ◽

pp. 3297-3333 ◽

Cited By ~ 1

Author(s):

M. Wisshak ◽

A. Form ◽

J. Jakobsen ◽

A. Freiwald

Keyword(s):

Cold Water ◽

Light Availability ◽

Euphotic Zone ◽

Carbonate Production ◽

Carbonate Budget ◽

Mass Properties ◽

Accretion Rates ◽

Key Factor ◽

Temperate Carbonate ◽

Factor Governing

Abstract. The rugged submarine topography of the Azores supports a diverse heterozoan association resulting in intense biotically-controlled carbonate production and accumulation. In order to characterise this cold-water (C) factory a 2-year experiment was carried out to study the biodiversity of hardground communities and for budgeting carbonate production and degradation along a bathymetrical transect from the intertidal to bathyal 500 m depth. Seasonal temperatures peak in September (above a thermocline) and bottom in March (stratification diminishes) with a decrease in amplitude and absolute values with depth, and with tidal-driven short-term fluctuations. Measured seawater stable isotope ratios and levels of dissolved nutrients decrease with depth, as do the calcium carbonate saturation states. The photosynthetic active radiation shows a base of the euphotic zone in ~70 m and a dysphotic limit in ~150 m depth. Bioerosion, being primarily a function of light availability for phototrophic endoliths and grazers feeding upon them, is ~10 times stronger on the illuminated upside versus the shaded underside of substrates in the photic zone, with maximum rates in the intertidal (−631 g/m2/yr). Rates rapidly decline towards deeper waters where bioerosion and carbonate accretion are slow and epibenthic/endolithic communities take years to mature. Accretion rates are highest in the lower euphotic zone (955 g/m2/yr), where the substrate is less prone to hydrodynamic force. Highest rates are found – inversely to bioerosion – on downward facing substrates, suggesting that bioerosion may be a key factor governing the preferential settlement and growth of calcareous epilithobionts on downward facing substrates. In context of a latitudinal gradient, the Azores carbonate cycling rates plot between known values from the cold-temperate Swedish Kosterfjord and the tropical Bahamas, with a total range of two orders in magnitude. Carbonate budget calculations for the bathymetrical transect yield a mean 266.9 kg of epilithic carbonate production, −54.6 kg of bioerosion, and 212.3 kg of annual net carbonate production per metre of coastline in the Azores C factory.

Download Full-text

Census Estimates of Algal and Epiphytic Carbonate Production Highlight Tropical Seagrass Meadows as Sediment Production Hotspots

Frontiers in Marine Science ◽

10.3389/fmars.2019.00120 ◽

2019 ◽

Vol 6 ◽

Cited By ~ 6

Author(s):

Chris T. Perry ◽

Michael A. Salter ◽

Kyle M. Morgan ◽

Alastair R. Harborne

Keyword(s):

Carbonate Production ◽

Seagrass Meadows ◽

Sediment Production

Download Full-text

A comparative analysis of the organic and inorganic carbon content of Halimeda and Penicillus (Chlorophyta, Bryopsidales) in a coastal subtropical lagoon

Botanica Marina ◽

10.1515/bot-2018-0095 ◽

2019 ◽

Vol 62 (4) ◽

pp. 323-326

Author(s):

Danielle Catherine Hatt ◽

Ligia Collado-Vides

Keyword(s):

Coastal Waters ◽

Inorganic Carbon ◽

Carbonate Sediment ◽

Term Study ◽

Sediment Production ◽

Long Term Study ◽

Organic And Inorganic Carbon ◽

Maximum Contribution ◽

Subtropical Lagoon

Abstract Standing stocks of the calcifying algae, Halimeda and Penicillus, have remained stable over the 10 years surveyed (2007–2017) in Florida Bay (USA), a subtropical lagoon. The maximum contribution of calcium carbonate (CaCO3; 779.75 g m−2) was lower compared to tropical lagoons. Halimeda was more abundant and had higher inorganic:organic carbon ratios compared to Penicillus. The abundance of Penicillus varied across the surveyed sites, Sprigger Bank, Bob Allen Keys, and Duck Key, while its inorganic:organic carbon ratios did not vary significantly. Our long-term study provides a critical baseline that can help understand fluctuations in carbonate sediment production by calcareous algae in subtropical coastal waters.

Download Full-text

The standing stock and CaCO3 contribution of Halimeda macroloba in the tropical seagrass-dominated ecosystem in Dongsha Island, the main island of Dongsha Atoll, South China Sea

Journal of the Marine Biological Association of the United Kingdom ◽

10.1017/s0025315420001113 ◽

2020 ◽

pp. 1-9

Author(s):

Jaruwan Mayakun ◽

Chen-Pan Liao ◽

Shao-Lun Liu

Keyword(s):

Growth Rate ◽

South China Sea ◽

South China ◽

Standing Stock ◽

Dry Weight ◽

Carbonate Production ◽

China Sea ◽

Carbonate Budget ◽

Marine Carbonate ◽

Dongsha Atoll

Abstract Calcareous green alga in the genus Halimeda are important contributors to the marine carbonate budget. Dongsha Island is located in the northernmost South China Sea and is a seagrass-dominated ecosystem with intermixed Halimeda macroloba patches, making it an excellent system to better examine the extent of carbonate contribution by H. macroloba in such an ecosystem. To this end, we examined the standing stock and actual CaCO3 contribution of H. macroloba in the seagrass-dominated ecosystem (herein Dongsha Island) and compared them with those in Halimeda-dominated ecosystems. The density, growth rate, calcification rate and CaCO3 content of H. macroloba at four life stages were investigated. The mean density of H. macroloba was around 8.82 ± 1.57 thalli m−2 and the estimated standing stock was 61,740 to 72,730 thalli. Thalli produced 1 to 2 new segments day−1, giving a growth rate of 0.003 ± 0.001 g dry weight thallus−1 day−1. Calculated algal biomass and annual areal production were 0.03 g m−2 and 9.66 g m−2 year−1. In each square metre of this area, H. macroloba produced 8.82 to 17.64 new segments day−1, accumulating 0.002 ± 0.001 g CaCO3 thallus−1 day−1 or around 6.44 g CaCO3 m−2 year−1. Mean CaCO3 content was 0.32 ± 0.05 g thallus−1. As expected, the growth rate and CaCO3 production of H. macroloba in Dongsha Island were lower than in other studies from Halimeda tropical ecosystems. Overall, this work provides the baseline of carbonate production of H. macroloba in Dongsha Island and relevant systems where the ecosystem is dominated by seagrasses.

Download Full-text

Carbonate sediment production in the equatorial continental shelf of South America: Quantifying Halimeda incrassata (Chlorophyta) contributions

Journal of South American Earth Sciences ◽

10.1016/j.jsames.2016.07.011 ◽

2016 ◽

Vol 72 ◽

pp. 1-6 ◽

Cited By ~ 5

Author(s):

Pedro Bastos de Macêdo Carneiro ◽

Jader Onofre de Morais

Keyword(s):

South America ◽

Continental Shelf ◽

Carbonate Sediment ◽

Sediment Production

Download Full-text

Changing dynamics of Caribbean reef carbonate budgets: emergence of reef bioeroders as critical controls on present and future reef growth potential

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2014.2018 ◽

2014 ◽

Vol 281 (1796) ◽

pp. 20142018 ◽

Cited By ~ 54

Author(s):

Chris T. Perry ◽

Gary N. Murphy ◽

Paul S. Kench ◽

Evan N. Edinger ◽

Scott G. Smithers ◽

...

Keyword(s):

Coral Cover ◽

Coral Community ◽

Growth Potential ◽

Reef Growth ◽

Carbonate Production ◽

Erosion Rates ◽

Caribbean Reef ◽

Carbonate Budget ◽

Coral Recovery ◽

Fundamental Shift

Coral cover has declined rapidly on Caribbean reefs since the early 1980s, reducing carbonate production and reef growth. Using a cross-regional dataset, we show that widespread reductions in bioerosion rates—a key carbonate cycling process—have accompanied carbonate production declines. Bioerosion by parrotfish, urchins, endolithic sponges and microendoliths collectively averages 2 G (where G = kg CaCO 3 m −2 yr −1 ) (range 0.96–3.67 G). This rate is at least 75% lower than that reported from Caribbean reefs prior to their shift towards their present degraded state. Despite chronic overfishing, parrotfish are the dominant bioeroders, but erosion rates are reduced from averages of approximately 4 to 1.6 G. Urchin erosion rates have declined further and are functionally irrelevant to bioerosion on most reefs. These changes demonstrate a fundamental shift in Caribbean reef carbonate budget dynamics. To-date, reduced bioerosion rates have partially offset carbonate production declines, limiting the extent to which more widespread transitions to negative budget states have occurred. However, given the poor prognosis for coral recovery in the Caribbean and reported shifts to coral community states dominated by slower calcifying taxa, a continued transition from production to bioerosion-controlled budget states, which will increasingly threaten reef growth, is predicted.

Download Full-text