/340479193_Unexpected_high_abyssal_ophiu

DeepCCZ: Deep-sea Mining Interests in the Clarion-Clipperton Zone: NOAA Office of Ocean Exploration and Research
▻https://oceanexplorer.noaa.gov/explorations/18ccz/background/mining/mining.html

https://oceanexplorer.noaa.gov/explorations/18ccz/background/mining/media/cerianthid-800.jpg

Polymetallic nodules are a potential mineral resource for copper, nickel, cobalt, iron, manganese, and rare earth elements—metals that are becoming important for modern life, since they are used in making electronics like rechargeable batteries and touch screens, among other things. These nodules are found in various deep ocean regions, including the deep Pacific and Indian Oceans.

The nodules of greatest mining interest are approximately potato-sized, and sit on the sediment surface across abyssal plains in the Clarion-Clipperton Zone (CCZ), a region spanning 5,000 kilometers (3,100 miles) across the central Pacific Ocean, at depths of ~4,000 - 5,500 meters (12,000 - 18,000 feet).

A modern Eldorado: deep sea mining at the Clarion Clipperton Zone
▻https://www.mining-technology.com/features/a-modern-eldorado-deep-sea-mining-at-the-clarion-clipperton-zone

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For those pinning their hopes on the future of deep sea mining, the Clarion Clipperton Zone (CCZ) is a modern-day El Dorado.

Lying between Hawaii and Mexico, and spanning some 1.7 million square miles – that’s bigger than India’s total land area – the seabed in this area of the Pacific Ocean is believed to be home to billions of dollars’ worth of nickel, cobalt and rare earth metals.

That’s what exploration players, who have tied their colours to the deep sea mining mast, are betting on. One such group is GSR (Global Sea Mineral Resources), a subsidiary of Belgium’s DEME Group, which in 2013 signed a 15-year contract with the International Seabed Authority (ISA) to prospect for ‘polymetallic nodules’ in the CCZ.

Having secured exclusive exploration rights in the zone, in 2017 GSR trialled the Patania I, the first ever tracked soil-testing device to crawl along an ocean bed at a depth of 4,500 metres. This was done with the purpose of collecting soil performance data needed in the development of dredging technology.

Caterpillars and cables: The Patania II deep sea nodule collector
At the end of last year, the group unveiled the Patania II, a deep sea nodule collector designed to comb the sea floor for polymetallic nodules. The launch overlapped with the start of a new scientific study initiated through JPI Oceans, a four-year intergovernmental initiative aimed at enabling cooperation in marine and maritime research.

According to GSR, the trialling of Patania II – named after the world’s fastest caterpillar – will assist in providing a clearer, scientific picture of the environmental aspects of the seafloor minerals industry.

However, things haven’t gone quite to plan. In March it was revealed that Patania II’s launch had been postponed due to damage to its umbilical – a critical, 5km-long cable that powers and connects the collector to its surface support vessel. As of early June, no new launch schedule has been confirmed, Peter Ogden, a GSR spokesperson confirmed to MINE.

BG - Distribution of free-living marine nematodes in the Clarion–Clipperton Zone: implications for future deep-sea mining scenarios
▻https://bg.copernicus.org/articles/16/3475/2019

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Abstract
Mining of polymetallic nodules in abyssal seafloor sediments promises to address the growing worldwide demand for metallic minerals. Given that prospective mining operations are likely to have profound impacts on deep seafloor communities, industrial investment has been accompanied by scientific involvement for the assessment of baseline conditions and provision of guidelines for environmentally sustainable mining practices.

Benthic meiofaunal communities were studied in four prospective mining areas of the Clarion–Clipperton Zone (CCZ) in the eastern Pacific Ocean, arranged in a southeast–northwest fashion coinciding with the productivity gradient in the area. Additionally, samples were collected from the Area of Particular Environmental Interest no. 3 (APEI-3) in the northwest of the CCZ, where mining will be prohibited and which should serve as a “source area” for the biota within the larger CCZ. Total densities in the 0–5 cm upper layer of the sediment were influenced by sedimentary characteristics, water depth and nodule density at the various sampling locations, indicating the importance of nodules for meiofaunal standing stock.

Nematodes were the most abundant meiobenthic taxon, and their assemblages were typically dominated by a few genera (generally 2–6) accounting for 40 %–70 % of all individuals, which were also widely spread along the CCZ and shared among all sampled license areas. However, almost half of the communities consisted of rare genera, each contributing less than 5 % to the overall abundances and displaying a distribution which was usually restricted to a single license area. The same observations (dominant and widely spread versus rare and scattered) could be made for the species of one of the dominant genera, Halalaimus, implying that it might be mainly these rare genera and species that will be vulnerable to mining-induced changes in their habitat.

avec la carte des concessions

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(PDF) Unexpected high abyssal ophiuroid diversity in polymetallic nodule fields of the northeast Pacific Ocean and implications for conservation
▻https://www.researchgate.net/publication/340479193_Unexpected_high_abyssal_ophiuroid_diversity_in_polymetallic_
▻https://www.researchgate.net/profile/Magdalini-Christodoulou/publication/340479193/figure/fig1/AS:877646569287680@1586258656464/Compilation-of-study-areas-in-the-Clarion-Clipperton-Zone-CCZ-and-in-t
Compilation of study areas in the Clarion-Clipperton Zone (CCZ) and in the DISCOL Experimental Area (DEA, Peru Basin). Insets represent detailed maps of sampling locations in the IFREMER, GSR, IOM, BGR and UKSRL exploration licence areas for polymetallic nodules as well as in APEI3 (ISA protected area) and the DEA. Copyright for shapefiles (for CCZ area): © International Seabed Authority 2009-2019; copyright for raster file (bathymetry): © Natural Earth 2009-2020.

quelques unes des bestioles décrites dans l’article précédent

▻https://www.researchgate.net/profile/Magdalini-Christodoulou/publication/340479193/figure/fig9/AS:877646615429125@1586258667680/Ophioleucidae-sp-sp37-a-dorsal-and-ventral-view-SO239-139-2-Asterosche
Ophioleucidae sp. (sp37): (a) dorsal and ventral view, SO239_139_2. Asteroschema sp. (sp12): (b) in situ (upper left and right), specimen collected with the ROV KIEL 6000 in dorsal (lower left) and ventral (lower right) view, SO239_2113. Ophiocantha cosmica: (c) in situ (left), specimen collected with the ROV KIEL 6000 in dorsal view (right), SO239_130. Scale bars: 2 mm (a); 1 cm (b, c). Copyright (for in situ photos) ROV KIEL 6000 Team/GEOMAR Kiel.

▻https://www.researchgate.net/figure/Ophioleucidae-sp-sp37-a-dorsal-and-ventral-view-SO239-139-2-Asterosche