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Coral Reefs of Cuba (2023)

Zlatarski, Vassil N. ; Reed, John K. ; Pomponi, Shirley A. ; [et al.]

Cham : Springer International Publishing | Cham : Imprint: Springer

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Keywords: Freshwater ecology. ; Marine ecology. ; Biodiversity. ; Zoology. ; Ecology . ; Oceanography. ; Conservation biology.

Description / Table of Contents: Part I. Introduction -- Chapter 1. Insights from Cuban Coral Reefs -- Part II. History -- Chapter 2. Research History of Corals and Coral Reefs in Cuba -- Part III. Description -- Chapter 3. Physical-Geographic Characteristics of Cuban Reefs -- Chapter 4. Outline of the Geology, Geomorphology and Evolution of the Late Qua-ternary Shelf and Uplifted Marine Terraces of Cuba; Tectonic and Sea Level Control of Present Day Coral Reef Distribution -- Chapter 5. A Remote Sensing Appraisal of the Extent and Geomorphological Diversity of the Coral Reefs of Cuba -- Part IV. Biota -- Chapter 6. Macrophytes Associated with Cuban Coral Reefs -- Chapter 7. Sponges: Conspicuous Inhabitants of the Cuban Coral Reefs and Their Potential as Bioindicators of Contamination -- Chapter 8. Species List of Cuban Stony Corals: Class Anthozoa, Order Scleractinia; Class Hydrozoa, Suborders Capitata and Filifera -- Chapter 9. Octocoral Forests: Distribution, Abundance, and Species Richness in Cuban Coral Reefs -- Chapter 10. Current State of Knowledge of Reef Mollusks in Cuba -- Chapter 11. Herbivory on Cuban Coral Reefs -- Chapter 12. Chronology of the Lionfish Invasion in Cuba and Evaluation of Impacts on Native Reef Fishes -- Chapter 13. Sharks and Rays in Cuban Coral Reefs: Ecology, Fisheries, and Conservation -- Chapter 14. Mesophotic Coral Ecosystems of Cuba -- Part V. Ecology, Conservation and Management -- Chapter 15. Status of Cuban Coral Reefs -- Chapter 16. Population Genetics of Cuba’s Scleractinian Corals -- Chapter 17. Multiple Cumulative Effects on Coral Reefs of the Northwestern Cuban Region -- Chapter 18. Guanahacabibes National Park: Research, Monitoring and Man-Agement for the Conservation of Coral Reefs -- Chapter 19. Ciénaga de Zapata Biosphere Reserve: Integrating Science with the Management of Coral Reefs -- Chapter 20. Coral Reefs in Cuban Marine Protected Areas -- Part VI. Economic Valuation -- Chapter 21. Economic Valuation of the Coral Reefs of Jardines de la Reina and Punta Francés National Parks, Cuba -- Chapter 22. The Economic Value of Coral Reefs in the Context of Marine Protected Areas: Experiences of the South Cuban Archipelago Project -- Chapter 23. Fish Can Be More Valuable Alive Than Dead.

Type of Medium: Online Resource

Pages: 1 Online-Ressource(XI, 438 p. 176 illus., 147 illus. in color.)

Edition: 1st ed. 2023.

ISBN: 9783031367199

Series Statement: Coral Reefs of the World 18

URL: https://doi.org/10.1007/978-3-031-36719-9

DOI: 10.1007/978-3-031-36719-9

Language: English

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Sustainability of deep-sea fisheries (2012)

Norse, Elliott A. ; Brooke, Sandra ; Cheung, William W. L. ; [et al.]

Elsevier

In: Marine Policy, 36 (2). pp. 307-320.

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Publication Date: 2019-09-23

Description: As coastal fisheries around the world have collapsed, industrial fishing has spread seaward and deeper in pursuit of the last economically attractive concentrations of fishable biomass. For a seafood-hungry world depending on the oceans' ecosystem services, it is crucial to know whether deep-sea fisheries can be sustainable. The deep sea is by far the largest but least productive part of the oceans, although in very limited places fish biomass can be very high. Most deep-sea fishes have life histories giving them far less population resilience/productivity than shallow-water fishes, and could be fished sustainably only at very low catch rates if population resilience were the sole consideration. But like old-growth trees and great whales, their biomass makes them tempting targets while their low productivity creates strong economic incentive to liquidate their populations rather than exploiting them sustainably (Clark's Law). Many deep-sea fisheries use bottom trawls, which often have high impacts on nontarget fishes (e.g., sharks) and invertebrates (e.g., corals), and can often proceed only because they receive massive government subsidies. The combination of very low target population productivity, nonselective fishing gear, economics that favor population liquidation and a very weak regulatory regime makes deep-sea fisheries unsustainable with very few exceptions. Rather, deep-sea fisheries more closely resemble mining operations that serially eliminate fishable populations and move on. Instead of mining fish from the least-suitable places on Earth, an ecologically and economically preferable strategy would be rebuilding and sustainably fishing resilient populations in the most suitable places, namely shallower and more productive marine ecosystems that are closer to markets. Highlights ► Industrial fishing has spread seaward and deeper in pursuit of wild fish biomass. ► Low productivity deep-sea fishes tempt fishermen to overexploit their populations. ► Azores hook-and-line black scabbardfish is a rare, apparently sustainable exception. ► Subsidies for trawling in poorly managed high seas areas incentivize overfishing. ► Recovering and fishing productive shelf fish populations is much more sustainable.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.marpol.2011.06.008

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Examination of Bathymodiolus childressi nutritional sources, isotopic niches, and food-web linkages at two seeps in the US Atlantic margin using stable isotope analysis and mixing models (2019)

Demopoulos, Amanda W.J. ; McClain-Counts, Jennifer P. ; Bourque, Jill R. ; [et al.]

Elsevier

In: Deep Sea Research Part I: Oceanographic Research Papers, 148 . pp. 53-66.

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Publication Date: 2022-01-31

Description: Chemosynthetic environments support distinct benthic communities capable of utilizing reduced chemical compounds for nutrition. Hundreds of methane seeps have been documented along the U.S. Atlantic margin (USAM), and detailed investigations at a few seeps have revealed distinct environments containing mussels, microbial mats, authigenic carbonates, and soft sediments. The dominant mussel, Bathymodiolus childressi, contains methanotrophic endosymbionts but is also capable of filter feeding, and stable isotope analysis (SIA) of mussel-shell periostracum suggests that these mussels are mixotrophic, assimilating multiple food resources. However, it is unknown whether mixotrophy is widespread or varies spatially and temporally. We used SIA (δ13C, δ15N, and δ34S) and an isotope mixing model (MixSIAR) to estimate resource contribution to B. childressi and characterize food webs at two seep sites (Baltimore Seep; 400 m and Norfolk Seep; 1500 m depths) along the USAM, and applied a linear mixed-effects model to explore the role of mussel population density and tissue type in influencing SIA variance. After controlling for location and temporal variation, isotopic variability was a function of proportion of live mussels present and tissue type. Isotopic differences were also spatially discrete, possibly reflecting variations in the underlying carbon source at the two sites. Low mussel δ13C values (∼−63‰) are consistent with a dependence on microbial methane. However, MixSIAR results revealed mixotrophy for mussels at both sites, implying a reliance on a mixture of methane and phytoplankton-derived particulate organic material. The mixing model results also reveal population density-driven patterns, suggesting that resource use is a function of live mussel abundance. Mussel isotopes differed by tissue type, with gill having the lowest δ15N values relative to muscle and mantle tissues. Based on mass balance equations, up to 79% of the dissolved inorganic carbon (DIC) of the pore fluids within the anaerobic oxidation of the methane zone is derived from methane and available to fuel upper slope deep-sea communities, such as fishes (Dysommina rugosa and Symphurus nebulosus), echinoderms (Odontaster robustus, Echinus wallisi, and Gracilechinus affinis), and shrimp, (Alvinocaris markensis). The presence of these seeps thereby increases the overall trophic and community diversity of the USAM continental slope. Given the presence of hundreds of seeps within the region, primary production at seeps may serve as an important, yet unquantified, energy source to the USAM deep-sea environment.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.dsr.2019.04.002

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Vailulu'u Seamount, Samoa : life and death on an active submarine volcano (2006)

Staudigel, Hubert ; Hart, Stanley R. ; Pile, Adele ; [et al.]

National Academy of Sciences

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Publication Date: 2022-05-25

Description: Author Posting. © National Academy of Sciences, 2006. This article is posted here by permission of National Academy of Sciences for personal use, not for redistribution. The definitive version was published in Proceedings of the National Academy of Sciences 103 (2006): 6448-6453, doi:10.1073/pnas.0600830103.

Description: Submersible exploration of the Samoan hotspot revealed a new, 300-m-tall, volcanic cone, named Nafanua, in the summit crater of Vailulu'u seamount. Nafanua grew from the 1,000-m-deep crater floor in 〈4 years and could reach the sea surface within decades. Vents fill Vailulu'u crater with a thick suspension of particulates and apparently toxic fluids that mix with seawater entering from the crater breaches. Low-temperature vents form Fe oxide chimneys in many locations and up to 1-m-thick layers of hydrothermal Fe floc on Nafanua. High-temperature (81°C) hydrothermal vents in the northern moat (945-m water depth) produce acidic fluids (pH 2.7) with rising droplets of (probably) liquid CO2. The Nafanua summit vent area is inhabited by a thriving population of eels (Dysommina rugosa) that feed on midwater shrimp probably concentrated by anticyclonic currents at the volcano summit and rim. The moat and crater floor around the new volcano are littered with dead metazoans that apparently died from exposure to hydrothermal emissions. Acid-tolerant polychaetes (Polynoidae) live in this environment, apparently feeding on bacteria from decaying fish carcasses. Vailulu'u is an unpredictable and very active underwater volcano presenting a potential long-term volcanic hazard. Although eels thrive in hydrothermal vents at the summit of Nafanua, venting elsewhere in the crater causes mass mortality. Paradoxically, the same anticyclonic currents that deliver food to the eels may also concentrate a wide variety of nektonic animals in a death trap of toxic hydrothermal fluids.

Description: This work was supported by the National Oceanic and Atmospheric Administration (NOAA) Oceans Exploration and the Hawaii Undersea Research Laboratory–NOAA Undersea Research Program, the National Science Foundation, the Australian Research Council, and the SERPENT program.

Repository Name: Woods Hole Open Access Server

Type: Article

Format: 5598800 bytes

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Invertebrate communities on historical shipwrecks in the western Atlantic : relation to islands (2017)

Meyer, Kirstin S. ; Brooke, Sandra ; Sweetman, Andrew K. ; [et al.]

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Publication Date: 2022-05-25

Description: Author Posting. © The Author(s), 2017. This is the author's version of the work. It is posted here under a nonexclusive, irrevocable, paid-up, worldwide license granted to WHOI. It is made available for personal use, not for redistribution. The definitive version was published in Marine Ecology Progress Series 566 (2017): 17-29, doi:10.3354/meps12058.

Description: Shipwrecks can be considered island-like habitats on the seafloor. We investigated the fauna of eight historical shipwrecks off the east coast of the U.S. to assess whether species distribution patterns on the shipwrecks fit models from classical island theory. Invertebrates on the shipwrecks included both sessile (sponges, anemones, hydroids) and motile (crustaceans, echinoderms) species. Invertebrate communities were significantly different among wrecks. The size and distance between wrecks influenced the biotic communities, much like on terrestrial islands. However, while wreck size influenced species richness (alpha diversity), distance to the nearest wreck influenced community composition (beta diversity). Alpha and beta diversity on the shipwrecks were thus influenced by different abiotic factors. We found no evidence of either nested patterns or non-random co-occurrence of morphotypes, suggesting that the taxa on a given shipwreck were randomly selected from the available taxon pool. Species present on the shipwrecks generally had one of two reproductive modes: most motile or solitary sessile species had long-duration planktotrophic larvae, while most encrusting or colonial sessile species had short-duration lecithotrophic larvae and underwent asexual reproduction by budding as adults. Short-duration larvae may recruit to their natal shipwreck, allowing them to build up dense populations and dominate the wreck surfaces. A high degree of dominance was indeed observed on the wrecks, with up to 80% of the fauna being accounted for by the most common species alone. By comparing the shipwreck communities to known patterns of succession in shallow water, we hypothesize that the shipwrecks are in a stage of mid-succession.

Description: This material is based upon work supported by the National Science Foundation Graduate Research Fellowship Program under Grant No. DGE-0829517. Funding for this project was supplied by the Bureau of Ocean Energy Management (BOEM), under contract to CSA Ocean Sciences, Inc. (contract M10PC00100) in partnership with the National Oceanographic 377 Partnership Program.

Keywords: Island biogeography ; Assembly rules ; Artificial reef ; Succession ; Benthic fauna ; Continental shelf ; ROV ; Video analysis

Repository Name: Woods Hole Open Access Server

Type: Preprint

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Cold-Water Coral in Aquaria: Advances and Challenges. A Focus on the Mediterranean (2019)

Orejas, Covadonga ; Taviani, Marco ; Ambroso, Stefano ; [et al.]

Springer

In: EPIC3Mediterranean Cold-Water Corals: Past, Present and Future, Book, Springer, 9, pp. 435-471, ISSN: 2213-719X

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Publication Date: 2019-10-23

Description: Knowledge on basic biological functions of organisms is essential to understand not only the role they play in the ecosystems but also to manage and protect their populations. The study of biological processes, such as growth, reproduction and physiology, which can be approached in situ or by collecting specimens and rearing them in aquaria, is particularly challenging for deep-sea organisms like cold-water corals. Field experimental work and monitoring of deep-sea populations is still a chimera. Only a handful of research institutes or companies has been able to install in situ marine observatories in the Mediterranean Sea or elsewhere, which facilitate a continuous monitoring of deep-sea ecosystems. Hence, today’s best way to obtain basic biological information on these organisms is (1) working with collected samples and analysing them post-mortem and / or (2) cultivating corals in aquaria in order to monitor biological processes and investigate coral behaviour and physiological responses under different experimental treatments. The first challenging aspect is the collection process, which implies the use of oceanographic research vessels in most occasions since these organisms inhabit areas between ca. 150 m to more than 1000 m depth, and specific sampling gears. The next challenge is the maintenance of the animals on board (in situations where cruises may take weeks) and their transport to home laboratories. Maintenance in the home laboratories is also extremely challenging since special conditions and set-ups are needed to conduct experimental studies to obtain information on the biological processes of these animals. The complexity of the natural environment from which the corals were collected cannot be exactly replicated within the laboratory setting; a fact which has led some researchers to question the validity of work and conclusions drawn from such undertakings. It is evident that aquaria experiments cannot perfectly reflect the real environmental and trophic conditions where these organisms occur, but: (1) in most cases we do not have the possibility to obtain equivalent in situ information and (2) even with limitations, they produce relevant information about the biological limits of the species, which is especially valuable when considering potential future climate change scenarios. This chapter includes many contributions from different authors and is envisioned as both to be a practical “handbook” for conducting cold-water coral aquaria work, whilst at the same time offering an overview on the cold-water coral research conducted in Mediterranean laboratories equipped with aquaria infrastructure. Experiences from Atlantic and Pacific laboratories with extensive experience with cold-water coral work have also contributed to this chapter, as their procedures are valuable to any researcher interested in conducting experimental work with cold-water corals in aquaria. It was impossible to include contributions from all laboratories in the world currently working experimentally with cold-water corals in the laboratory, but at the conclusion of the chapter we attempt, to our best of our knowledge, to supply a list of several laboratories with operational cold-water coral aquaria facilities.

Repository Name: EPIC Alfred Wegener Institut

Type: Inbook , peerRev

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Corrigendum to “Insights into methane dynamics from analysis of authigenic carbonates and chemosynthetic mussels at newly-discovered Atlantic Margin seeps” [Earth Planet. Sci. Lett. 449 (2016) 332–344] (2017)

Prouty, Nancy G. ; Sahy, Diana ; Ruppel, Carolyn D. ; [et al.]

Elsevier

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Publication Date: 2022-05-26

Description: This paper is not subject to U.S. copyright. The definitive version was published in Earth and Planetary Science Letters 475 (2017): 268, doi:10.1016/j.epsl.2017.07.037.

Repository Name: Woods Hole Open Access Server

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Insights into methane dynamics from analysis of authigenic carbonates and chemosynthetic mussels at newly-discovered Atlantic Margin seeps (2016)

Prouty, Nancy G. ; Sahy, Diana ; Ruppel, Carolyn D. ; [et al.]

Elsevier

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Publication Date: 2022-05-26

Description: This paper is not subject to U.S. copyright. The definitive version was published in Earth and Planetary Science Letters 449 (2016): 332–344, doi:10.1016/j.epsl.2016.05.023.

Description: The recent discovery of active methane venting along the US northern and mid-Atlantic margin represents a new source of global methane not previously accounted for in carbon budgets from this region. However, uncertainty remains as to the origin and history of methane seepage along this tectonically inactive passive margin. Here we present the first isotopic analyses of authigenic carbonates and methanotrophic deep-sea mussels, Bathymodiolus sp., and the first direct constraints on the timing of past methane emission, based on samples collected at the upper slope Baltimore Canyon (∼385 m water depth) and deepwater Norfolk (∼1600 m) seep fields within the area of newly-discovered venting. The authigenic carbonates at both sites were dominated by aragonite, with an average View the MathML sourceδC13 signature of −47‰−47‰, a value consistent with microbially driven anaerobic oxidation of methane-rich fluids occurring at or near the sediment–water interface. Authigenic carbonate U and Sr isotope data further support the inference of carbonate precipitation from seawater-derived fluids rather than from formation fluids from deep aquifers. Carbonate stable and radiocarbon (View the MathML sourceδC13 and View the MathML sourceΔC13) isotope values from living Bathymodiolus sp. specimens are lighter than those of seawater dissolved inorganic carbon, highlighting the influence of fossil carbon from methane on carbonate precipitation. U–Th dates on authigenic carbonates suggest seepage at Baltimore Canyon between 14.7±0.6 ka14.7±0.6 ka to 15.7±1.6 ka15.7±1.6 ka, and at the Norfolk seep field between 1.0±0.7 ka1.0±0.7 ka to 3.3±1.3 ka3.3±1.3 ka, providing constraint on the longevity of methane efflux at these sites. The age of the brecciated authigenic carbonates and the occurrence of pockmarks at the Baltimore Canyon upper slope could suggest a link between sediment delivery during Pleistocene sea-level lowstand, accumulation of pore fluid overpressure from sediment compaction, and release of overpressure through subsequent venting. Calculations show that the Baltimore Canyon site probably has not been within the gas hydrate stability zone (GHSZ) in the past 20 ka, meaning that in-situ release of methane from dissociating gas hydrate cannot be sustaining the seep. We cannot rule out updip migration of methane from dissociation of gas hydrate that occurs farther down the slope as a source of the venting at Baltimore Canyon, but consider that the history of rapid sediment accumulation and overpressure may play a more important role in methane emissions at this site.

Description: Funding for this project (sponsored by the National Oceanographic Partnership Program) included USGS Terrestrial, Freshwater, and Marine Environments Program through the Outer Continental shelf study, Coastal and Marine Geology Program, and the Bureau of Ocean Energy Management (BOEM) contract number M10PC00100 (contracted to CSA Ocean Sciences, Inc.). C.R. was supported by USGS–DOE Interagency Agreements DE-FE000291 and 0023495.

Keywords: Authigenic carbonate ; Cold seep ; AOM ; Chemosynthesis ; Mid-Atlantic margin ; Isotope geochemistry

Repository Name: Woods Hole Open Access Server

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