Fine-scale nutrient and carbonate system dynamics around cold-water coral reefs in the northeast Atlantic

An overview of polynoid scale worms known to occur on cold-water coral reefs of the northeast Atlantic and the Mediterranean Sea is given, including a key for identification of species. Harmothoe oculinarum (Storm, 1879), H. vesiculosa Ditlevsen, 1917, and Leucia violacea (Storm, 1879) comb. nov. are redescribed. A lectotype is designated for H. vesiculosa and the generic status of Leucia violacea (Storm, 1879) comb. nov. and Neolagisca jeffreysi (McIntosh, 1876) comb. nov. are changed. The biogeography of the species is discussed.

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Seabed mapping for selecting cold-water coral protection areas on Hatton Bank, Northeast Atlantic

ICES Journal of Marine Science ◽

10.1093/icesjms/fsp170 ◽

2009 ◽

Vol 66 (9) ◽

pp. 2013-2025 ◽

Cited By ~ 20

Author(s):

P. Durán Muñoz ◽

M. Sayago-Gil ◽

J. Cristobo ◽

S. Parra ◽

A. Serrano ◽

...

Keyword(s):

Deep Sea ◽

Ad Hoc ◽

Cold Water ◽

Interdisciplinary Approach ◽

Western Slope ◽

Northeast Atlantic ◽

Fisheries Science ◽

Seabed Mapping ◽

Del Rio ◽

Water Coral

Abstract Durán Muñoz, P., Sayago-Gil, M., Cristobo, J., Parra, S., Serrano, A., Díaz del Rio, V., Patrocinio, T., Sacau, M., Murillo, F. J., Palomino, D., and Fernández-Salas, L. M. 2009. Seabed mapping for selecting cold-water coral protection areas on Hatton Bank, Northeast Atlantic. – ICES Journal of Marine Science, 66: 2013–2025. Research into vulnerable marine ecosystems (VMEs) on the high seas and the impacts of bottom fishing and ad hoc management measures are high priority today thanks to UN General Assembly Resolution 61/105. An interdisciplinary methodology (specifically designed for selecting cold-water coral protection areas) and a case study focused on the Hatton Bank (NE Atlantic) are presented. This interdisciplinary approach, developed under the ECOVUL/ARPA project, was based on conventional fisheries science, geomorphology, benthic ecology, and sedimentology. It contributes to defining practical criteria for identifying VMEs, to improving knowledge of their distribution off Europe's continental shelf, and to providing advice on negative fishing impacts and habitat protection. The approach was used to identify the bottom-trawl deep-sea fishery footprint on the western slope of Hatton Bank, to map the main fishing grounds and related deep-sea habitats (1000–1500 m deep), and to study the interactions between fisheries and cold-water corals. The results lead to a proposal to close the outcrop area (4645 km2) located on the western slope of Hatton Bank as a conservation measure for cold-water corals.

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Measuring Sound at a Cold-Water Coral Reef to Assess the Impact of COVID-19 on Noise Pollution

Frontiers in Marine Science ◽

10.3389/fmars.2021.674702 ◽

2021 ◽

Vol 8 ◽

Author(s):

Laurence H. De Clippele ◽

Denise Risch

Keyword(s):

Coral Reef ◽

Coral Reefs ◽

Sea Level ◽

Cold Water ◽

Noise Pollution ◽

Ecosystem Functions ◽

Noise Levels ◽

Level Height ◽

Water Coral

This study compares the noise levels at the cold-water coral Tisler reef, before and after the closure of the border between Norway and Sweden, which occurred as a direct result of the COVID-19 pandemic. The Tisler reef is a marine protected area located under a ferry “highway” that connects Norway and Sweden. Cold-water coral reefs are recognised as being important hotspots of both biodiversity and biomass, they function as breeding and nursing grounds for commercially important fish and are essential in providing ecosystem functions. Whilst studies have shown that fishery, ocean warming, and acidification threaten them, the effects of noise pollution on cold-water coral reefs remains unstudied. To study the severity of noise pollution at the Tisler reef, a long-term acoustic recorder was deployed from 29 January 2020 until 26 May 2020. From 15 March COVID-19 lockdown measures stopped passenger vessel traffic between Norway and Sweden. This study found that the overall noise levels were significantly lower after border closure, due to reduced ferry traffic, wind speeds, and sea level height. When comparing the median hourly noise levels of before vs. after border closure, this study measured a significant reduction in the 63–125 Hz 1/3 octave band noise levels of 8.94 ± 0.88 (MAD) dB during the day (07:00:00–19:59:59) and 1.94 ± 0.11 (MAD) dB during the night (20:00:00–06:59:59). Since there was no ferry traffic during the night, the drop in noise levels at night was likely driven by seasonal changes, i.e., the reduction in wind speed and sea level height when transitioning from winter to spring. Taking into account this seasonal effect, it can be deduced that the COVID-19 border closure reduced the noise levels in the 63–125 Hz 1/3 octave bands at the Tisler reef by 7.0 ± 0.99 (MAD) dB during the day. While the contribution of, and changes in biological, weather-related and geophysical sound sources remain to be assessed in more detail, understanding the extent of anthropogenic noise pollution at the Tisler cold-water coral reef is critical to guide effective management to ensure the long-term health and conservation of its ecosystem functions.

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