Abstract
In this work, we integrate five case studies harboring vulnerable deep-sea benthic habitats in different geological settings from mid latitude NE Atlantic Ocean (24–42° N). Data and images of specific deep-sea habitats were acquired with Remoted Operated Vehicle (ROV) sensors (temperature, salinity, potential density, O2, CO2, and CH4). Besides documenting some key vulnerable deep-sea habitats, this study shows that the distribution of some deep-sea coral aggregations (including scleractinians, gorgonians, and antipatharians), deep-sea sponge aggregations and other deep-sea habitats are influenced by water masses’ properties. Our data support that the distribution of scleractinian reefs and aggregations of other deep-sea corals, from subtropical to north Atlantic could be dependent of the latitudinal extents of the Antarctic Intermediate Waters (AAIW) and the Mediterranean Outflow Waters (MOW). Otherwise, the distribution of some vulnerable deep-sea habitats is influenced, at the local scale, by active hydrocarbon seeps (Gulf of Cádiz) and hydrothermal vents (El Hierro, Canary Island). The co-occurrence of deep-sea corals and chemosynthesis-based communities has been identified in methane seeps of the Gulf of Cádiz. Extensive beds of living deep-sea mussels (Bathymodiolus mauritanicus) and other chemosymbiotic bivalves occur closely to deep-sea coral aggregations (e.g., gorgonians, black corals) that colonize methane-derived authigenic carbonates.
Highlights
Introduction conditions of the Creative CommonsMaintaining the sustainable functioning of the global biosphere requires protection of deep-sea ecosystems, because they face major changes related to human and climate-induced impacts [1]
Atlantic Ocean from 23◦ N to 42◦ N latitudes, are presented in this work. These were targeted with multibeam bathymetry echosounder (MBES) mapping, Remoted Operated Vehicle (ROV)-mounted CTD data of the benthic layer and identification and sampling of deep-sea habitats
The water mass properties drivers are modulated by the effects, at regional and local scale, of methane seeps or low-temperature hydrothermal fields after submarine eruptions
Summary
Introduction conditions of the Creative CommonsMaintaining the sustainable functioning of the global biosphere requires protection of deep-sea ecosystems, because they face major changes related to human and climate-induced impacts [1]. High-resolution seabed mapping is essential for improving the current knowledge and understanding of deep-seafloor morphology, key geological processes (including sedimentary depositional and erosional processes), habitat distribution, and typology as well as availability of mineral deposits and energy resources, among other aspects. Seabed mapping is valuable for more applied purposes such as the deployment of submarine cables and pipelines, detection of marine geohazards, development of early warning systems for volcanic eruptions, tsunamis, and earthquakes, prevention of pollution, management of fisheries, analysis of potential environmental impacts associated with deep-sea mining and for safer shipping. Legend: FAO Taxa the maintodifferent masses defined by [33]:contours the main different defined by [33]: NACW, AAIW, MOW(http://www.fao.org/in-action/vulnerable-marineand NADW defined by [33].
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