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Hotspot Ecosystem Research and Man's Impact On European Seas

April 15, 2024

Hotspot Ecosystem Research and Man's Impact On European Seas (HERMIONE) is an international multidisciplinary project, started in April 2009, that studies deep-sea ecosystems.[1][2] HERMIONE scientists study the distribution of hotspot ecosystems, how they function and how they interconnect, partially in the context of how these ecosystems are being affected by climate change[3] and impacted by humans through overfishing, resource extraction, seabed installations (oil platforms, etc.) and pollution. Major aims of the project are to understand how humans are affecting the deep-sea environment and to provide policy makers with accurate scientific information, enabling effective management strategies to protect deep sea ecosystems. The HERMIONE project is funded by the European Commission's Seventh Framework Programme, and is the successor to the HERMES project, which concluded in March 2009.[4]

HERMIONE project logo

Introduction edit

Europe's deep-ocean margin, from the Arctic to the Iberian Margin, and across the Mediterranean to the Black Sea, spans a distance of over 15,000 km and hosts a number of diverse habitats and ecosystems. Deep water coral reefs, undersea mountains populated by a multitude of organisms, vast submarine canyon systems, and hydrothermal vents are some of the features contained therein.[5] The traditional view of the deep-sea realm as a hostile and barren place was discredited long ago, and scientists now know that much of Europe's deep sea is rich and diverse.[6]

However, the deep sea is increasingly threatened by humans: most of this deep-ocean frontier lies within Europe's Exclusive Economic Zone (EEZ) and has significant potential for the exploitation of biological, energy, and mineral resources. Research and exploration over the last two decades has shown clear signs of direct and indirect anthropogenic impacts in the deep sea, resulting from such activities as overfishing,[7] littering and pollution. This raises concerns because deep-sea processes and ecosystems are not only important for the marine web of life, but also fundamentally contribute to the global biogeochemical cycle.[citation needed]

Continuing with the knowledge obtained by the HERMES project (EC FP6), which contributed significantly to our understanding of deep-sea ecosystems,[8] the HERMIONE project investigates ecosystems at critical sites on Europe's deep-ocean margin, aiming to make major advances in knowledge of their distribution and functioning, and their contribution to ecosystem goods and services.[clarification needed] HERMIONE places special emphasis on human impact on the deep sea and on the translation of scientific information into science policy for the sustainable use of marine resources. To design and implement effective governance strategies and management plans to protect our deep seas for the future, understanding the extent, natural dynamics and interconnection of ocean ecosystems, and integrating socio-economic research with natural science, are important. To achieve this, HERMIONE uses a highly interdisciplinary and integrated approach, engaging experts in biology, ecology, biodiversity, oceanography, geology, sedimentology, geophysics and biogeochemistry, who will work alongside socio-economists and policy-makers.

Hotspot research edit

The HERMIONE project focuses on deep-sea "hotspot" ecosystems including submarine canyons, open slopes and deep basins, chemosynthetic environments, deep water coral reefs, and seamounts. Hotspot ecosystems support high species diversity, numbers of individuals, or both, and are therefore important in maintaining margin-wide biodiversity and abundance.[9] HERMIONE research ranges from investigation of the ecosystems' dimensions, distribution, interconnection and functioning, to understanding the potential impacts of climate change and anthropogenic disturbance. The ultimate objective is to provide stakeholders and policymakers with the scientific knowledge necessary to support deep-sea governance, sustainable management and conservation of these ecosystems.

To obtain the data needed, HERMIONE scientists are spending over 1000 days at sea, using more than 50 research vessels across Europe. Sharing vessels and equipment between partners will bring benefits through shared knowledge, expertise and data, and will also maximise the research effort, increasing efficiency and productivity. State-of-the-art technology will be used, with Remotely Operated Vehicles (ROVs) one of the critical pieces of equipment being used for a wide range of delicate manoeuvres and high-resolution surveys, from precision sampling of methane gas at cold seeps to microbathymetry mapping to examine the structure of the seabed. Large arrays of instrumented moorings, shared by different partner institutions, will be deployed in common experimental areas, allowing HERMIONE to develop experimental strategies beyond any national capacity.

Study areas edit

 
Map of HERMIONE areas of scientific research

The HERMIONE study sites were selected on the following basis:

  • The Arctic because of its importance in monitoring climate change;
  • Nordic margin with abundant cold-water corals, extensive hydrocarbon exploration and the Haakon-Mosby mud volcano (HMMV) natural laboratory;
  • Celtic margin with a mid-latitude canyon, cold water corals and the long term Porcupine Abyssal Plain (PAP) monitoring site;
  • Portuguese margin with the highly diverse Nazare and Setubal canyons;
  • Seamounts in the Atlantic and western Mediterranean as important biodiversity hotspots potentially under threat;
  • Mid Atlantic Ridge (MAR) ESONET site to link cold seep to hot seep chemosynthetic studies;
  • Mediterranean cold water cascading sites in the Gulf of Lions and outflows of the Adriatic and Aegean Seas.

The HMMV, PAP, MAR and central Mediterranean sites link to the ESONET long-term monitoring sites and will provide valuable background information.

Hotspot ecosystems edit

Cold-water coral reefs edit

Deep water coral reefs are found along the northeast Atlantic and central Mediterranean margins, and are important biodiversity hotspots.[10][11] The recent HERMES project lists more than 2000 species associated with cold-water coral reefs worldwide.[12] As well as flourishing live coral, the dead coral frameworks and rubble that are frequently found close by attract a myriad of fauna from the microscopic to the mega,[13] and may be fundamental in coral ecosystem replenishment. Coral reefs provide a habitat for fish,[14] a refuge from predators, a rich food source, a nursery for young fish, and are also potential sources of a wide range of medicines to treat ailments from cancer to cardiovascular disease.

There are several known coral hotspot areas on Europe's deep-ocean margin, including the Scandinavian, Rockall-Porcupine and central Mediterranean margins, and there remain many questions about them, such as how each of the sites are connected to one another,[15] how they arose, what drives the distribution of the reefs,[16][17] how the larvae disperse and settle, how the corals and associated species reproduce, finding their physiological thresholds, how they will fare with increased ocean warming,[18][19] and whether ocean warming induces a spread of coral reefs further north into the Arctic Ocean. New research will also build on previous work to define the physical environment around cold-water coral reefs such as hydrodynamic and sedimentary regimes, which will help to understand biological responses.[20][21]

HERMIONE scientists use cutting-edge technology to try to answer these questions.[2] High-resolution mapping of the seafloor will be carried out to determine the location and distribution of cold-water corals, and photographic observations will be made to assess changes in the status of known reefs over time, such as their response to climatic variation or their recovery from destruction by fishing trawlers. To assess biodiversity and its relationship with environmental factors such as climate change, DNA barcoding and other molecular techniques will be used.

Submarine canyons edit

Submarine canyons are deep, steep-sided valleys that form on continental margins. Stretching from the shelf to the deep sea, they dissect much of the European margin. They are one of the most complex seascapes known to humans; their rugged topography and challenging environmental conditions mean that they are also one of the least explored. Advances in technology over the last two decades have allowed scientists to uncover some of the mysteries of canyons, the size of which often rival the Grand Canyon,[22] USA.

One of the most important discoveries is that canyons are major sources and sinks for sediment and organic matter on continental margins.[23][24] They act as fast-track pathways for sediment and organic matter from the shelf to the deep sea,[25] and can act as temporary depots for sediment and carbon storage. Particle flux through canyons has been found to be between two and four times greater than on the open slope,[25] though the transfer of particles through canyons is thought to be largely "event-driven",[26][27][28] which introduces a highly variable aspect to canyon conditions. Determining what drives sediment transport and deposition within canyons is one of the major challenges for HERMIONE.

The capacity of canyons to focus and concentrate organic matter can promote high abundances and diversity of fauna. However, variability in environmental conditions and topography is very high, both within and between canyons, and this is reflected in the variability of the structure and dynamics of the biological communities.[29] Our understanding of biological processes in canyons has greatly improved with the use of submersibles and ROVs, but this research has also revealed that the relationships between fauna and canyons are more complex than previously thought.[30][31] The diversity of submarine canyons and their fauna means that it is difficult to make generalisations that can be used to create policies for canyon ecosystem management. It is important that the role of canyons in maintaining biodiversity, and how potential anthropogenic impacts may affect this,[32][33] is better understood. HERMIONE will address this challenge by examining canyon ecosystems from different biogeochemical provinces and topographic settings, in light of the complex interactions among habitat (topography, water masses, currents), mass and energy transfer, and biological communities.

Open slopes and deep basins edit

Open slopes and deep basins make up > 90% of the ocean floor and 65% of the Earth's surface, and many of the goods and services provided by the deep sea (e.g., oil, gas, climate regulation and food) are produced and stored by them. They are intricately involved in global biogeochemical and ecological processes, and so are essential for the functioning of our biosphere and human wellbeing.

Recent research in the HERMES (EC-FP6) project gathered a large body of information on local biodiversity at large scales, different latitudes and in different hotspot ecosystems, but the research also highlighted the high degree of complexity of deep-sea habitats. This information is fundamental to our understanding of the factors that control biodiversity at much larger scales, from hundreds to thousands of kilometres. HERMIONE will conduct further studies on the mosaic of habitats found in deep-sea slopes and basins, and will investigate the relationships within and between these habitats, their biodiversity and ecology, and their interconnection with other hotspot ecosystems.

Investigating the impacts of anthropogenic activities and climate change in the deep sea is a theme that runs through all HERMIONE research. To the biological communities on open slopes and in deep basins, seafloor warming through climate change is a major threat. Up to 85% of methane reservoirs along the continental margin could be destabilised, which would not only release climate-warming methane gas into the atmosphere, but would also have unknown and potentially devastating consequences on benthic communities. The role of climatic variation on deep-sea benthos is not well understood, although large-scale changes in the structure of seafloor communities have been observed over the last two decades. The use of long-term, deep-sea observatories, e.g., the Hausgarten deep-sea observatory in the Arctic and the time-series analysis of the Catalan margin and Southern Adriatic Sea, will help HERMIONE scientists to examine recent changes in benthic communities, and to study decadal variability in physical processes, such as the dense shelf water cascading events in submarine canyons.[28]

HERMIONE aims to provide quantitative estimates of the potential consequences of biodiversity loss on ecosystem functioning, to examine how deep-sea benthos adapt to large-scale changes, and, for the first time, to create conceptual models integrating deep-sea biodiversity and quantitative analyses of ecosystem functioning and processes.

Seamounts edit

Seamounts are underwater mountains that rise from the depths of the ocean, and whose summits can sometimes be found just a few hundred metres below the sea surface. To be classified as a seamount the summit must be 1000 m higher than the surrounding seafloor,[34] and under this definition there are an estimated 1000–2800 seamounts in the Atlantic Ocean and around 60 in the Mediterranean Sea.[35]

Seamounts enhance water flow through localised tides, eddies, and upwelling, and these physical processes may enhance primary production.[36] Seamounts may therefore be considered as hotspots of marine life; fauna benefit from the enhanced hydrodynamics and phytoplankton supply, and thrive on the slopes and summits. Suspension feeders, such as gorgonian sea fans and the cold-water corals like Lophelia pertusa, often dominate the rich benthic (seafloor-dwelling) communities.[37] The enhanced abundance and diversity of fauna is not limited to benthic species, as fish are known to aggregate over seamounts.[38] Unfortunately, this knowledge has led to increasing commercial exploitation of seamount fish by the fishing industry, and a number of seamount fish populations have already been depleted. Part of HERMIONE research will assess the threats and impacts of human activities on seamounts, including comparing data from seamounts in different stages of fisheries exploitation to understand more about the impacts of fishing activities., both on target species and non-target species, and their habitats.

Despite our increasing knowledge on seamounts, there is still very little known about the relationships between their ecosystem functioning and biodiversity, and that of the surrounding areas. This information is vital in order to improve our understanding of connectivity between seamount hotspots and adjacent areas, and HERMIONE research will aim to discover whether seamounts act as centres of speciation (the evolution of new species), or if they play a role as "stepping stones", allowing fauna to colonise and disperse across the oceans.

Chemosynthetic ecosystems edit

Chemosynthetic environments - such as hot vents, cold seeps, mud volcanoes and sulphidic brine pools - show the highest biomass and productivity of all deep-sea ecosystems. The chemicals found in the fluids, gases and mud that escape from such systems provide an energy source for chemosynthetic bacteria and archaea, which are the primary producers in these systems. A huge variety of fauna profits from the association with chemosynthetic microbes, supporting large communities that can exist independently of sunlight. Some of these environments, such as methane (cold) seeps, can support up to 50,000 times more biomass than communities that rely on photosynthetic production alone.[39] Owing to the extreme gradients and diversity in physical and chemical factors, hydrothermal vents also remain incredibly fascinating ecosystems. HERMIONE researchers aim to illustrate the tight coupling between geosphere and biosphere processes, as well as their immense heterogeneity and interconnectivity, by observing and comparing the spatial and temporal variation of chemosynthetic environments in European Sea’s.

Methane cycling and carbonate formation by microorganisms in chemosynthetic environments have implications for the control of greenhouse gases.[40][41] Methane can be trapped and stored under the seabed as a gas hydrate, and under different conditions, can either be controlled by microbial consumption, or can escape into the surrounding seawater, and ultimately the atmosphere. Our understanding of the biological controls of methane seepage and feedback mechanisms for global warming is limited. The distribution and structure of cold seep communities can act as an indicator for changes in methane fluxes in the deep sea, e.g. by seafloor warming.[42] Using multibeam echosounder data and 3D seismic data with in situ studies at seep sites, and by investigating the life histories of fauna at such ecosystems, HERMIONE scientists aim to understand more about their interconnectivity and resilience, and the implications for climate change.

The great variety of fauna present in chemosynthetic environments is a real challenge to scientists. Only a tiny fraction of microorganisms at vents and seeps has been identified, and a huge amount is still to be discovered. Their identification, their association with fauna, and the relationship between their diversity, function and habitat, are vital areas of research as biological communities act as important filters, controlling up to 100% of vent and seep emissions.[42] By using DNA barcoding and genome analysis in addition to traditional methods of identification and experimentation, HERMIONE scientists will study the relationship between community structure and ecosystem functioning at a variety of vents, seeps, brine pools and mud volcanoes.

Socio-economics, governance and science-policy interfaces edit

With increasing ocean exploration over the last two decades has come the realisation that humans have had an extensive impact on the world’s oceans, not just close to our shores, but also reaching down into the deep sea. From destructive fishing practices and exploitation of mineral resources to pollution and litter, evidence of human impact can be found in virtually all deep-sea ecosystems.[43][44] In response, the international community has set a series of ambitious goals aimed at protecting the marine environment and its resources for future generations. Three of these initiatives, decided on by world leaders during the 2002 World Summit on Sustainable Development (Johannesburg), are to achieve a significant reduction in biodiversity loss by 2010, to introduce an ecosystems approach to marine resource assessment and management by 2010, and to designate a network of marine protected areas by 2012. A crucial requirement for implementing these is the availability of high-quality scientific data and knowledge, as well as effective science-policy interfaces to ensure the policy relevance of research and to enable the rapid translation of scientific information into science policy.

HERMIONE aims to provide this by filling the knowledge gap about threatened deep-sea ecosystems and their current status with respect to anthropogenic impacts (e.g. litter, chemical contamination). Socio-economists and natural scientists work together in HERMIONE, researching the socio-economics of anthropogenic impacts, mapping human activities that affect the deep sea, assessing the potential for valuing deep-sea ecosystem goods and services, studying governance options and designing and implementing real-time science-policy interfaces.

HERMIONE natural and social science results will provide national, regional (EU), and global policy-makers and other stakeholders with the information needed to establish policies to ensure the sustainable use of the deep ocean and conservation of deep-sea ecosystems.

References edit

  1. ^ HERMIONE website, 2017-10-14 at the Wayback Machine
  2. ^ a b Weaver et al. (2009). "The future of integrated deep-sea research in Europe: The HERMIONE project". 2011-05-13 at the Wayback Machine Oceanography 22 (1), March 2009.
  3. ^ Schloesser, Manfred (2009). European deep-sea research: Climate changes and deep-sea ecosystems in the Eastern Mediterranean Sea. Innovations Report (website).
  4. ^ . Archived from the original on 2011-04-25. Retrieved 2009-12-09.
  5. ^ Schloesser, Manfred (2009). Ausbrüche des Tiefsee-Schlammvulkans Haakon Mosby ("Outbreaks of the Deep Sea Mud Volcano Haakon Mosby"). Innovations Report (website).
  6. ^ Marum - Zentrum für Marine Umweltwissenschaften an der Universität Bremen (2009). Erstmals lebende Tiefseeaustern im Mittelmeer entdeckt! ("For the First Time, Living Deep Sea Oysters Discovered in the Mediterranean!"). GMX (website).
  7. ^ Bailey et al. (2009). "Long-term changes in deep-water fish populations in the northeast Atlantic: a deeper reaching effect of fisheries?". Proceedings of the Royal Society B 10.1098/rspb.2009.0098.
  8. ^ See for instance the March 2009 issue of Oceanography 2010-02-25 at the Wayback Machine, dedicated to HERMES, with 16 articles on its contributions. (PDFs viewable at website.)
  9. ^ "Ecological hotspots".
  10. ^ van Oevelen et al. (2009). "The cold-water coral community as hotspot of carbon cycling on continental margins: A food-web analysis from Rockall Bank (northeast Atlantic)". 2011-07-20 at the Wayback Machine Limnology and Oceanography 54 (6), November 2009.
  11. ^ Freiwald and Roberts (eds) (2005) "Cold-water Corals and Ecosystems" Springer, Berlin Heidelberg, 1243 pp
  12. ^ Henry et al. (2007). "Biodiversity and ecological composition of macrobenthos on cold-water coral mounds and adjacent off-mound habitat in the bathyal Porcupine Seabight, NE Atlantic". Deep-Sea Research Part I 54 (4), April 2007
  13. ^ Gheerardyn et al. (2009). "Diversity and community structure of harpacticoid copepods associated with cold-water coral substrates in the Porcupine Seabight (North-East Atlantic)".[dead link] Helgoland Marine Research 10.1007/s10152-009-0166-7
  14. ^ Costello et al. (2005). "Role of cold-water Lophelia pertusa coral reefs as fish habitat in the NE Atlantic", in: Freiwald, A. & Roberts, J.M. (eds) Cold-water Corals and Ecosystems. Springer, Berlin Heidelberg, 771-805.
  15. ^ Henry et al. (2006). "First record of Bedotella armata(Cnidaria:Hydrozoa) from the Porcupine Seabight:do north-east Atlantic carbonate mound fauna have Mediterranean ancestors?" 2009-07-26 at the Wayback Machine Biodiversity Records
  16. ^ Gass and Roberts (2006). "The occurrence of the cold-water coral Lophelia pertusa (Scleractinia) on oil and gas platforms in the North Sea: Colony growth, recruitment and environmental controls on distribution". Marine Pollution Bulletin 52, May 2006
  17. ^ Dolan et al. (2008). "Modelling the local distribution of cold-water corals in relation to bathymetric variables: Adding spatial context to deep-sea video data" Deep-Sea Research Part I 55 (11), November 2008
  18. ^ Guinotte et al. (2006). "Will human-induced changes in seawater chemistry alter the distribution of deep-sea scleractinian corals?" Frontiers in Ecology and the Environment 4 (3)
  19. ^ Dodds et al. (2007). "Metabolic tolerance of the cold-water coral Lophelia pertusa (Scleractinia) to temperature and dissolved oxygen change" Journal of Experimental Marine Biology and Ecology 349 (2), October 2007
  20. ^ Duineveld et al. (2007). "Trophic structure of a cold-water corals mound community (Rockall Bank, NE Atlantic) in relation to the near-bottom particle supply and current regime"[permanent dead link] Bulletin of Marine Science 81 (3), November 2007
  21. ^ Dullo et al. (2008) "Cold-water coral growth in relation to the hydrography of the Celtic and Nordic European Continental Margin". Marine Ecology Progress Series 371, November 2008
  22. ^ Tyler et al. (2009). "Europe's Grand Canyon" 2010-02-25 at the Wayback Machine Oceanography 22 (1), March 2009
  23. ^ Shepard et al. (1979). "Currents in submarine canyons and other seavalleys" AAPG Studies in Geology (8), Tulsa, OK
  24. ^ Carson et al. (1986) "Modern sediment dispersal and accumulation in Quinault submarine canyon - a summary" Marine Geology 71 (1-2) p1-13
  25. ^ a b De Stigter et al. (2007). "Recent sediment transport and deposition in the Nazaré Canyon, Portuguese continental margin"[dead link] Marine Geology 46, December 2007
  26. ^ Palanques et al. (2008). "Storm-driven shelf-to-canyon suspended sediment transport at the southwestern Gulf of Lions" Continental Shelf Research 28 (15) p1947-1956, August 2008
  27. ^ Arzola et al. (2008). "Sedimentary features and processes in the Nazaré and Setúbal submarine canyons, west Iberian margin"[dead link] Marine Geology 250 (1-2) p64-88, April 2008.
  28. ^ a b Canals et al. (2006). "Flushing submarine canyons" Nature 444, p3574-357, September 2006
  29. ^ Pattenden (2009) "The influence of submarine canyons on the structure and dynamics of megafauna communities" PhD Thesis, University of Southampton
  30. ^ Garcia et al. (2007). "Distribution of meiobenthos in the Nazaré canyon and adjacent slope (western Iberian Margin)in relation to sedimentary composition" Marine Ecology Progress Series 340, p207-220, June 2007
  31. ^ Pattenden et al. (in prep.) "Megafauna community composition in two contrasting submarine canyons"
  32. ^ Richter et al. (2009). "Dispersal of natural and anthropogenic lead through submarine canyons at the Portuguese margin"[dead link] Deep-Sea Research Part I 56, February 2009
  33. ^ Martin et al. (2008). "Effect of commercial trawling on the deep sedimentation in a Mediterranean submarine canyon" Marine Geology 252 (3-4), July 2008
  34. ^ Wessel, P. (2007) "Seamount characteristics" p. 3-25 in Seamounts: Ecology, Fisheries and Conservation. T.J. Pitcher, T. Morato, P.J.B. Hart, M.R. Clark, N. Haggan, and R.S. Santos (eds), Fish and Aquatic Resource Series, Blackwell, Oxford, UK.
  35. ^ Kitchingman, A., Lai, S., Morato, T., and Pauly, D. (2007). "How many seamounts are there and where are they located?" p.26-40 in Seamounts: Ecology, Fisheries and Conservation. T.J. Pitcher, T. Morato, P.J.B. Hart, M.R. Clark, N. Haggan, and R.S. Santos (eds), Fish and Aquatic Resource Series, Blackwell, Oxford, UK.
  36. ^ White, M., Bashmachnikov, I., Aristegui, H., and Martins, A. (2007). "Physical processes and seamount productivity" p.65-84 in Seamounts: Ecology, Fisheries and Conservation. T.J. Pitcher, T. Morato, P.J.B. Hart, M.R. Clark, N. Haggan, and R.S. Santos (eds), Fish and Aquatic Resource Series, Blackwell, Oxford, UK.
  37. ^ Rogers, A., Baco, A., Griffiths, H., Hart, T., and Hall-Spencer, J.M. (2007). "Corals on seamounts" p.141-169 in Seamounts: Ecology, Fisheries and Conservation. T.J. Pitcher, T. Morato, P.J.B. Hart, M.R. Clark, N. Haggan, and R.S. Santos (eds), Fish and Aquatic Resource Series, Blackwell, Oxford, UK.
  38. ^ Morato, T. and Clark, M.R. (2007). "Seamount fishes: Ecology and life histories" p.170-188 in Seamounts: Ecology, Fisheries and Conservation. T.J. Pitcher, T. Morato, P.J.B. Hart, M.R. Clark, N. Haggan, and R.S. Santos (eds), Fish and Aquatic Resource Series, Blackwell, Oxford, UK.
  39. ^ Sibuet, M. and Olu-Le Roy, K. (2002)"Cold seep communities on continental margins: Structure and quantitative distribution relative to geological and fluid venting patterns". Pp. 235-251 in Ocean Margin Systems Wefer, G., Billett, D.S.M., Hebbeln, D., Jorgensen, B.B., Schluter, M. and Van Weering, T.C.M. (eds), Springer Verlag, Berlin
  40. ^ Boetius, A. et al. (2007) "A marine microbial consortium apparently mediating anaerobic oxidation of methane" Nature 407, p.623-626, August 2000
  41. ^ Parkes, R.J. et al. (2007) "Biogeochemistry and biodiversity of methane cycling in subsurface marine sediments (Skagerrak, Denmark)" Environmental Microbiology, 9, p.1146-1161
  42. ^ a b Niemann H. et al.(2006) "Novel microbial communities of the Haakon Mosby mud volcano and their role as a methane sink" Nature 443, p.854-858, August 2006
  43. ^ Bailey, D.M., Collins, M.A., Gordon, J.D.M., Zuur, A.F., and Priede, I.G. (2009) "Long-term changes in deep-water fish populations in the northeast Atlantic: a deeper reaching effect of fisheries?"Proceedings of the Royal Society B doi:10.1098/rspb.2009.0098, March 2009
  44. ^ Galil, B.S., Golik, A., and Turkay, M. (1995) "Litter at the bottom of the sea: A sea bed survey in the Eastern Mediterranean" Marine Pollution Bulletin 30, p22-24, January 1995

April 15, 2024
hotspot, ecosystem, research, impact, european, seas, hermione, international, multidisciplinary, project, started, april, 2009, that, studies, deep, ecosystems, hermione, scientists, study, distribution, hotspot, ecosystems, they, function, they, interconnect. Hotspot Ecosystem Research and Man s Impact On European Seas HERMIONE is an international multidisciplinary project started in April 2009 that studies deep sea ecosystems 1 2 HERMIONE scientists study the distribution of hotspot ecosystems how they function and how they interconnect partially in the context of how these ecosystems are being affected by climate change 3 and impacted by humans through overfishing resource extraction seabed installations oil platforms etc and pollution Major aims of the project are to understand how humans are affecting the deep sea environment and to provide policy makers with accurate scientific information enabling effective management strategies to protect deep sea ecosystems The HERMIONE project is funded by the European Commission s Seventh Framework Programme and is the successor to the HERMES project which concluded in March 2009 4 HERMIONE project logo Contents 1 Introduction 2 Hotspot research 2 1 Study areas 3 Hotspot ecosystems 3 1 Cold water coral reefs 3 2 Submarine canyons 3 3 Open slopes and deep basins 3 4 Seamounts 3 5 Chemosynthetic ecosystems 4 Socio economics governance and science policy interfaces 5 ReferencesIntroduction editEurope s deep ocean margin from the Arctic to the Iberian Margin and across the Mediterranean to the Black Sea spans a distance of over 15 000 km and hosts a number of diverse habitats and ecosystems Deep water coral reefs undersea mountains populated by a multitude of organisms vast submarine canyon systems and hydrothermal vents are some of the features contained therein 5 The traditional view of the deep sea realm as a hostile and barren place was discredited long ago and scientists now know that much of Europe s deep sea is rich and diverse 6 However the deep sea is increasingly threatened by humans most of this deep ocean frontier lies within Europe s Exclusive Economic Zone EEZ and has significant potential for the exploitation of biological energy and mineral resources Research and exploration over the last two decades has shown clear signs of direct and indirect anthropogenic impacts in the deep sea resulting from such activities as overfishing 7 littering and pollution This raises concerns because deep sea processes and ecosystems are not only important for the marine web of life but also fundamentally contribute to the global biogeochemical cycle citation needed Continuing with the knowledge obtained by the HERMES project EC FP6 which contributed significantly to our understanding of deep sea ecosystems 8 the HERMIONE project investigates ecosystems at critical sites on Europe s deep ocean margin aiming to make major advances in knowledge of their distribution and functioning and their contribution to ecosystem goods and services clarification needed HERMIONE places special emphasis on human impact on the deep sea and on the translation of scientific information into science policy for the sustainable use of marine resources To design and implement effective governance strategies and management plans to protect our deep seas for the future understanding the extent natural dynamics and interconnection of ocean ecosystems and integrating socio economic research with natural science are important To achieve this HERMIONE uses a highly interdisciplinary and integrated approach engaging experts in biology ecology biodiversity oceanography geology sedimentology geophysics and biogeochemistry who will work alongside socio economists and policy makers Hotspot research editThe HERMIONE project focuses on deep sea hotspot ecosystems including submarine canyons open slopes and deep basins chemosynthetic environments deep water coral reefs and seamounts Hotspot ecosystems support high species diversity numbers of individuals or both and are therefore important in maintaining margin wide biodiversity and abundance 9 HERMIONE research ranges from investigation of the ecosystems dimensions distribution interconnection and functioning to understanding the potential impacts of climate change and anthropogenic disturbance The ultimate objective is to provide stakeholders and policymakers with the scientific knowledge necessary to support deep sea governance sustainable management and conservation of these ecosystems To obtain the data needed HERMIONE scientists are spending over 1000 days at sea using more than 50 research vessels across Europe Sharing vessels and equipment between partners will bring benefits through shared knowledge expertise and data and will also maximise the research effort increasing efficiency and productivity State of the art technology will be used with Remotely Operated Vehicles ROVs one of the critical pieces of equipment being used for a wide range of delicate manoeuvres and high resolution surveys from precision sampling of methane gas at cold seeps to microbathymetry mapping to examine the structure of the seabed Large arrays of instrumented moorings shared by different partner institutions will be deployed in common experimental areas allowing HERMIONE to develop experimental strategies beyond any national capacity Study areas edit nbsp Map of HERMIONE areas of scientific researchThe HERMIONE study sites were selected on the following basis The Arctic because of its importance in monitoring climate change Nordic margin with abundant cold water corals extensive hydrocarbon exploration and the Haakon Mosby mud volcano HMMV natural laboratory Celtic margin with a mid latitude canyon cold water corals and the long term Porcupine Abyssal Plain PAP monitoring site Portuguese margin with the highly diverse Nazare and Setubal canyons Seamounts in the Atlantic and western Mediterranean as important biodiversity hotspots potentially under threat Mid Atlantic Ridge MAR ESONET site to link cold seep to hot seep chemosynthetic studies Mediterranean cold water cascading sites in the Gulf of Lions and outflows of the Adriatic and Aegean Seas The HMMV PAP MAR and central Mediterranean sites link to the ESONET long term monitoring sites and will provide valuable background information Hotspot ecosystems editCold water coral reefs edit Deep water coral reefs are found along the northeast Atlantic and central Mediterranean margins and are important biodiversity hotspots 10 11 The recent HERMES project lists more than 2000 species associated with cold water coral reefs worldwide 12 As well as flourishing live coral the dead coral frameworks and rubble that are frequently found close by attract a myriad of fauna from the microscopic to the mega 13 and may be fundamental in coral ecosystem replenishment Coral reefs provide a habitat for fish 14 a refuge from predators a rich food source a nursery for young fish and are also potential sources of a wide range of medicines to treat ailments from cancer to cardiovascular disease There are several known coral hotspot areas on Europe s deep ocean margin including the Scandinavian Rockall Porcupine and central Mediterranean margins and there remain many questions about them such as how each of the sites are connected to one another 15 how they arose what drives the distribution of the reefs 16 17 how the larvae disperse and settle how the corals and associated species reproduce finding their physiological thresholds how they will fare with increased ocean warming 18 19 and whether ocean warming induces a spread of coral reefs further north into the Arctic Ocean New research will also build on previous work to define the physical environment around cold water coral reefs such as hydrodynamic and sedimentary regimes which will help to understand biological responses 20 21 HERMIONE scientists use cutting edge technology to try to answer these questions 2 High resolution mapping of the seafloor will be carried out to determine the location and distribution of cold water corals and photographic observations will be made to assess changes in the status of known reefs over time such as their response to climatic variation or their recovery from destruction by fishing trawlers To assess biodiversity and its relationship with environmental factors such as climate change DNA barcoding and other molecular techniques will be used Submarine canyons edit Submarine canyons are deep steep sided valleys that form on continental margins Stretching from the shelf to the deep sea they dissect much of the European margin They are one of the most complex seascapes known to humans their rugged topography and challenging environmental conditions mean that they are also one of the least explored Advances in technology over the last two decades have allowed scientists to uncover some of the mysteries of canyons the size of which often rival the Grand Canyon 22 USA One of the most important discoveries is that canyons are major sources and sinks for sediment and organic matter on continental margins 23 24 They act as fast track pathways for sediment and organic matter from the shelf to the deep sea 25 and can act as temporary depots for sediment and carbon storage Particle flux through canyons has been found to be between two and four times greater than on the open slope 25 though the transfer of particles through canyons is thought to be largely event driven 26 27 28 which introduces a highly variable aspect to canyon conditions Determining what drives sediment transport and deposition within canyons is one of the major challenges for HERMIONE The capacity of canyons to focus and concentrate organic matter can promote high abundances and diversity of fauna However variability in environmental conditions and topography is very high both within and between canyons and this is reflected in the variability of the structure and dynamics of the biological communities 29 Our understanding of biological processes in canyons has greatly improved with the use of submersibles and ROVs but this research has also revealed that the relationships between fauna and canyons are more complex than previously thought 30 31 The diversity of submarine canyons and their fauna means that it is difficult to make generalisations that can be used to create policies for canyon ecosystem management It is important that the role of canyons in maintaining biodiversity and how potential anthropogenic impacts may affect this 32 33 is better understood HERMIONE will address this challenge by examining canyon ecosystems from different biogeochemical provinces and topographic settings in light of the complex interactions among habitat topography water masses currents mass and energy transfer and biological communities Open slopes and deep basins edit Open slopes and deep basins make up gt 90 of the ocean floor and 65 of the Earth s surface and many of the goods and services provided by the deep sea e g oil gas climate regulation and food are produced and stored by them They are intricately involved in global biogeochemical and ecological processes and so are essential for the functioning of our biosphere and human wellbeing Recent research in the HERMES EC FP6 project gathered a large body of information on local biodiversity at large scales different latitudes and in different hotspot ecosystems but the research also highlighted the high degree of complexity of deep sea habitats This information is fundamental to our understanding of the factors that control biodiversity at much larger scales from hundreds to thousands of kilometres HERMIONE will conduct further studies on the mosaic of habitats found in deep sea slopes and basins and will investigate the relationships within and between these habitats their biodiversity and ecology and their interconnection with other hotspot ecosystems Investigating the impacts of anthropogenic activities and climate change in the deep sea is a theme that runs through all HERMIONE research To the biological communities on open slopes and in deep basins seafloor warming through climate change is a major threat Up to 85 of methane reservoirs along the continental margin could be destabilised which would not only release climate warming methane gas into the atmosphere but would also have unknown and potentially devastating consequences on benthic communities The role of climatic variation on deep sea benthos is not well understood although large scale changes in the structure of seafloor communities have been observed over the last two decades The use of long term deep sea observatories e g the Hausgarten deep sea observatory in the Arctic and the time series analysis of the Catalan margin and Southern Adriatic Sea will help HERMIONE scientists to examine recent changes in benthic communities and to study decadal variability in physical processes such as the dense shelf water cascading events in submarine canyons 28 HERMIONE aims to provide quantitative estimates of the potential consequences of biodiversity loss on ecosystem functioning to examine how deep sea benthos adapt to large scale changes and for the first time to create conceptual models integrating deep sea biodiversity and quantitative analyses of ecosystem functioning and processes Seamounts edit Seamounts are underwater mountains that rise from the depths of the ocean and whose summits can sometimes be found just a few hundred metres below the sea surface To be classified as a seamount the summit must be 1000 m higher than the surrounding seafloor 34 and under this definition there are an estimated 1000 2800 seamounts in the Atlantic Ocean and around 60 in the Mediterranean Sea 35 Seamounts enhance water flow through localised tides eddies and upwelling and these physical processes may enhance primary production 36 Seamounts may therefore be considered as hotspots of marine life fauna benefit from the enhanced hydrodynamics and phytoplankton supply and thrive on the slopes and summits Suspension feeders such as gorgonian sea fans and the cold water corals like Lophelia pertusa often dominate the rich benthic seafloor dwelling communities 37 The enhanced abundance and diversity of fauna is not limited to benthic species as fish are known to aggregate over seamounts 38 Unfortunately this knowledge has led to increasing commercial exploitation of seamount fish by the fishing industry and a number of seamount fish populations have already been depleted Part of HERMIONE research will assess the threats and impacts of human activities on seamounts including comparing data from seamounts in different stages of fisheries exploitation to understand more about the impacts of fishing activities both on target species and non target species and their habitats Despite our increasing knowledge on seamounts there is still very little known about the relationships between their ecosystem functioning and biodiversity and that of the surrounding areas This information is vital in order to improve our understanding of connectivity between seamount hotspots and adjacent areas and HERMIONE research will aim to discover whether seamounts act as centres of speciation the evolution of new species or if they play a role as stepping stones allowing fauna to colonise and disperse across the oceans Chemosynthetic ecosystems edit Chemosynthetic environments such as hot vents cold seeps mud volcanoes and sulphidic brine pools show the highest biomass and productivity of all deep sea ecosystems The chemicals found in the fluids gases and mud that escape from such systems provide an energy source for chemosynthetic bacteria and archaea which are the primary producers in these systems A huge variety of fauna profits from the association with chemosynthetic microbes supporting large communities that can exist independently of sunlight Some of these environments such as methane cold seeps can support up to 50 000 times more biomass than communities that rely on photosynthetic production alone 39 Owing to the extreme gradients and diversity in physical and chemical factors hydrothermal vents also remain incredibly fascinating ecosystems HERMIONE researchers aim to illustrate the tight coupling between geosphere and biosphere processes as well as their immense heterogeneity and interconnectivity by observing and comparing the spatial and temporal variation of chemosynthetic environments in European Sea s Methane cycling and carbonate formation by microorganisms in chemosynthetic environments have implications for the control of greenhouse gases 40 41 Methane can be trapped and stored under the seabed as a gas hydrate and under different conditions can either be controlled by microbial consumption or can escape into the surrounding seawater and ultimately the atmosphere Our understanding of the biological controls of methane seepage and feedback mechanisms for global warming is limited The distribution and structure of cold seep communities can act as an indicator for changes in methane fluxes in the deep sea e g by seafloor warming 42 Using multibeam echosounder data and 3D seismic data with in situ studies at seep sites and by investigating the life histories of fauna at such ecosystems HERMIONE scientists aim to understand more about their interconnectivity and resilience and the implications for climate change The great variety of fauna present in chemosynthetic environments is a real challenge to scientists Only a tiny fraction of microorganisms at vents and seeps has been identified and a huge amount is still to be discovered Their identification their association with fauna and the relationship between their diversity function and habitat are vital areas of research as biological communities act as important filters controlling up to 100 of vent and seep emissions 42 By using DNA barcoding and genome analysis in addition to traditional methods of identification and experimentation HERMIONE scientists will study the relationship between community structure and ecosystem functioning at a variety of vents seeps brine pools and mud volcanoes Socio economics governance and science policy interfaces editWith increasing ocean exploration over the last two decades has come the realisation that humans have had an extensive impact on the world s oceans not just close to our shores but also reaching down into the deep sea From destructive fishing practices and exploitation of mineral resources to pollution and litter evidence of human impact can be found in virtually all deep sea ecosystems 43 44 In response the international community has set a series of ambitious goals aimed at protecting the marine environment and its resources for future generations Three of these initiatives decided on by world leaders during the 2002 World Summit on Sustainable Development Johannesburg are to achieve a significant reduction in biodiversity loss by 2010 to introduce an ecosystems approach to marine resource assessment and management by 2010 and to designate a network of marine protected areas by 2012 A crucial requirement for implementing these is the availability of high quality scientific data and knowledge as well as effective science policy interfaces to ensure the policy relevance of research and to enable the rapid translation of scientific information into science policy HERMIONE aims to provide this by filling the knowledge gap about threatened deep sea ecosystems and their current status with respect to anthropogenic impacts e g litter chemical contamination Socio economists and natural scientists work together in HERMIONE researching the socio economics of anthropogenic impacts mapping human activities that affect the deep sea assessing the potential for valuing deep sea ecosystem goods and services studying governance options and designing and implementing real time science policy interfaces HERMIONE natural and social science results will provide national regional EU and global policy makers and other stakeholders with the information needed to establish policies to ensure the sustainable use of the deep ocean and conservation of deep sea ecosystems References edit HERMIONE website Archived 2017 10 14 at the Wayback Machine a b Weaver et al 2009 The future of integrated deep sea research in Europe The HERMIONE project Archived 2011 05 13 at the Wayback Machine Oceanography 22 1 March 2009 Schloesser Manfred 2009 European deep sea research Climate changes and deep sea ecosystems in the Eastern Mediterranean Sea Innovations Report website HERMES website Archived from the original on 2011 04 25 Retrieved 2009 12 09 Schloesser Manfred 2009 Ausbruche des Tiefsee Schlammvulkans Haakon Mosby Outbreaks of the Deep Sea Mud Volcano Haakon Mosby Innovations Report website Marum Zentrum fur Marine Umweltwissenschaften an der Universitat Bremen 2009 Erstmals lebende Tiefseeaustern im Mittelmeer entdeckt For the First Time Living Deep Sea Oysters Discovered in the Mediterranean GMX website Bailey et al 2009 Long term changes in deep water fish populations in the northeast Atlantic a deeper reaching effect of fisheries Proceedings of the Royal Society B 10 1098 rspb 2009 0098 See for instance the March 2009 issue of Oceanography Archived 2010 02 25 at the Wayback Machine dedicated to HERMES with 16 articles on its contributions PDFs viewable at website Ecological hotspots van Oevelen et al 2009 The cold water coral community as hotspot of carbon cycling on continental margins A food web analysis from Rockall Bank northeast Atlantic Archived 2011 07 20 at the Wayback Machine Limnology and Oceanography 54 6 November 2009 Freiwald and Roberts eds 2005 Cold water Corals and Ecosystems Springer Berlin Heidelberg 1243 pp Henry et al 2007 Biodiversity and ecological composition of macrobenthos on cold water coral mounds and adjacent off mound habitat in the bathyal Porcupine Seabight NE Atlantic Deep Sea Research Part I 54 4 April 2007 Gheerardyn et al 2009 Diversity and community structure of harpacticoid copepods associated with cold water coral substrates in the Porcupine Seabight North East Atlantic dead link Helgoland Marine Research 10 1007 s10152 009 0166 7 Costello et al 2005 Role of cold water Lophelia pertusa coral reefs as fish habitat in the NE Atlantic in Freiwald A amp Roberts J M eds Cold water Corals and Ecosystems Springer Berlin Heidelberg 771 805 Henry et al 2006 First record of Bedotella armata Cnidaria Hydrozoa from the Porcupine Seabight do north east Atlantic carbonate mound fauna have Mediterranean ancestors Archived 2009 07 26 at the Wayback Machine Biodiversity Records Gass and Roberts 2006 The occurrence of the cold water coral Lophelia pertusa Scleractinia on oil and gas platforms in the North Sea Colony growth recruitment and environmental controls on distribution Marine Pollution Bulletin 52 May 2006 Dolan et al 2008 Modelling the local distribution of cold water corals in relation to bathymetric variables Adding spatial context to deep sea video data Deep Sea Research Part I 55 11 November 2008 Guinotte et al 2006 Will human induced changes in seawater chemistry alter the distribution of deep sea scleractinian corals Frontiers in Ecology and the Environment 4 3 Dodds et al 2007 Metabolic tolerance of the cold water coral Lophelia pertusa Scleractinia to temperature and dissolved oxygen change Journal of Experimental Marine Biology and Ecology 349 2 October 2007 Duineveld et al 2007 Trophic structure of a cold water corals mound community Rockall Bank NE Atlantic in relation to the near bottom particle supply and current regime permanent dead link Bulletin of Marine Science 81 3 November 2007 Dullo et al 2008 Cold water coral growth in relation to the hydrography of the Celtic and Nordic European Continental Margin Marine Ecology Progress Series 371 November 2008 Tyler et al 2009 Europe s Grand Canyon Archived 2010 02 25 at the Wayback Machine Oceanography 22 1 March 2009 Shepard et al 1979 Currents in submarine canyons and other seavalleys AAPG Studies in Geology 8 Tulsa OK Carson et al 1986 Modern sediment dispersal and accumulation in Quinault submarine canyon a summary Marine Geology 71 1 2 p1 13 a b De Stigter et al 2007 Recent sediment transport and deposition in the Nazare Canyon Portuguese continental margin dead link Marine Geology 46 December 2007 Palanques et al 2008 Storm driven shelf to canyon suspended sediment transport at the southwestern Gulf of Lions Continental Shelf Research 28 15 p1947 1956 August 2008 Arzola et al 2008 Sedimentary features and processes in the Nazare and Setubal submarine canyons west Iberian margin dead link Marine Geology 250 1 2 p64 88 April 2008 a b Canals et al 2006 Flushing submarine canyons Nature 444 p3574 357 September 2006 Pattenden 2009 The influence of submarine canyons on the structure and dynamics of megafauna communities PhD Thesis University of Southampton Garcia et al 2007 Distribution of meiobenthos in the Nazare canyon and adjacent slope western Iberian Margin in relation to sedimentary composition Marine Ecology Progress Series 340 p207 220 June 2007 Pattenden et al in prep Megafauna community composition in two contrasting submarine canyons Richter et al 2009 Dispersal of natural and anthropogenic lead through submarine canyons at the Portuguese margin dead link Deep Sea Research Part I 56 February 2009 Martin et al 2008 Effect of commercial trawling on the deep sedimentation in a Mediterranean submarine canyon Marine Geology 252 3 4 July 2008 Wessel P 2007 Seamount characteristics p 3 25 in Seamounts Ecology Fisheries and Conservation T J Pitcher T Morato P J B Hart M R Clark N Haggan and R S Santos eds Fish and Aquatic Resource Series Blackwell Oxford UK Kitchingman A Lai S Morato T and Pauly D 2007 How many seamounts are there and where are they located p 26 40 in Seamounts Ecology Fisheries and Conservation T J Pitcher T Morato P J B Hart M R Clark N Haggan and R S Santos eds Fish and Aquatic Resource Series Blackwell Oxford UK White M Bashmachnikov I Aristegui H and Martins A 2007 Physical processes and seamount productivity p 65 84 in Seamounts Ecology Fisheries and Conservation T J Pitcher T Morato P J B Hart M R Clark N Haggan and R S Santos eds Fish and Aquatic Resource Series Blackwell Oxford UK Rogers A Baco A Griffiths H Hart T and Hall Spencer J M 2007 Corals on seamounts p 141 169 in Seamounts Ecology Fisheries and Conservation T J Pitcher T Morato P J B Hart M R Clark N Haggan and R S Santos eds Fish and Aquatic Resource Series Blackwell Oxford UK Morato T and Clark M R 2007 Seamount fishes Ecology and life histories p 170 188 in Seamounts Ecology Fisheries and Conservation T J Pitcher T Morato P J B Hart M R Clark N Haggan and R S Santos eds Fish and Aquatic Resource Series Blackwell Oxford UK Sibuet M and Olu Le Roy K 2002 Cold seep communities on continental margins Structure and quantitative distribution relative to geological and fluid venting patterns Pp 235 251 in Ocean Margin Systems Wefer G Billett D S M Hebbeln D Jorgensen B B Schluter M and Van Weering T C M eds Springer Verlag Berlin Boetius A et al 2007 A marine microbial consortium apparently mediating anaerobic oxidation of methane Nature 407 p 623 626 August 2000 Parkes R J et al 2007 Biogeochemistry and biodiversity of methane cycling in subsurface marine sediments Skagerrak Denmark Environmental Microbiology 9 p 1146 1161 a b Niemann H et al 2006 Novel microbial communities of the Haakon Mosby mud volcano and their role as a methane sink Nature 443 p 854 858 August 2006 Bailey D M Collins M A Gordon J D M Zuur A F and Priede I G 2009 Long term changes in deep water fish populations in the northeast Atlantic a deeper reaching effect of fisheries Proceedings of the Royal Society B doi 10 1098 rspb 2009 0098 March 2009 Galil B S Golik A and Turkay M 1995 Litter at the bottom of the sea A sea bed survey in the Eastern Mediterranean Marine Pollution Bulletin 30 p22 24 January 1995 Retrieved from https en wikipedia org w index php title Hotspot Ecosystem Research and Man 27s Impact On European Seas amp oldid 1210372010, 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