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European Multidisciplinary Seafloor and water column Observatory

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European Multidisciplinary Seafloor and water-column Observatory (EMSO)
HeadquartersRome, Italy
Membership13 involved countries
Websitehttp://www.emso-eu.org

European Multidisciplinary Seafloor and water-column Observatory (EMSO) is a large-scale European distributed Research Infrastructure[1] for ocean observation, enabling real-time interactive long term monitoring of ocean processes. EMSO allows study of the interaction between the geosphere, the biosphere, the hydrosphere, and the lithosphere; including natural hazards, climate change, and marine ecosystems. EMSO nodes have been deployed at key sites in European seas, starting from the Arctic, through the Atlantic and Mediterranean, to the Black Sea.

Overview

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EMSO is a consortium of partners sharing a common strategic framework of scientific facilities (data, instruments, computing and storage capacity). EMSO is a European Research Infrastructure Consortium (ERIC), a specific legal form created for pan-European large-scale research infrastructures by the European Commission that facilitates the establishment and operation of Research Infrastructures with European interest.. EMSO is one of the environmental RIs [2] on the Roadmap of the European Strategy Forum on Research Infrastructures (ESFRI). The ESRFI Roadmap identifies RIs of pan-European importance that corresponds to the long term needs of European research communities.

EMSO Sites Map

The different EMSO nodes are designed to address topics of regional importance: the biodiversity of mid ocean hot vents in the Azores region, the rapidly changing environmental conditions affecting the geosphere and biosphere of the Arctic, the deep-water ventilation in the eastern Mediterranean, the active seismicity and the associated geo-hazards of the Anatolian region.[3] EMSO infrastructure has the capacity to observe the deep and open ocean, below, at and above the seafloor, at the European scale, utilizing both stand-alone observing systems, and nodes connected to shore stations through high throughput fibre optic cable.[4] The mission of EMSO is to unite these regional observatories into a common research infrastructure, to implement more generic sensor packages to collect synoptic data series on oceanographic features of more than regional interest, to bring these data together in a uniform format accessible to the general public, and to ensure maintenance of this research infrastructure over a longer time-span than easily maintained by national funding programs.[5]


Ocean observatories

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The global oceans cover 70% of the surface of the globe, consist of 95% of the living space, and are the core momentum of our planet's physical, chemical, and biological cycles. As underlined in recent policy documents such as the Galway Statement [6] and Belmont Challenge[7], in order to understand the changes predicted in the coming decades, EMSO aims to have a continuous presence in the oceans; and in order to understand both the slow moving and rapid catastrophes, EMSO seeks to have continuous real-time data from which to learn and to derive adaptation and early warning systems. Ocean observatories provide power and communications to allow a sustained interactive presence in the ocean. This challenge can only be addressed as part of an international cooperation between USA,[8] Canada, Japan, Australia, Europe and other interested countries where EMSO takes a role for the European side.

Major science themes

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The deployment of the EMSO distributed observatory nodes is allowing researchers to get useful data in order to understand the behaviour of the oceans and their impact on human society. In particular, EMSO collects data concerning the following main scientific fields:[9]

  • Geosciences: gas hydrate stability, seabed fluid flows, sub-marine landslides, geo-hazard early warning, mid-ocean ridge volcanism.
  • Physical Oceanography: ocean warming, deep-ocean circulation, benthic and water-column interactions.
  • Biogeochemistry: ocean acidification and the solubility pump, the biological pump, hypoxia, continental shelf exchange, deep-ocean biogeochemical fluxes.
  • Marine Ecology: climate forcing of ecosystems, molecules to microbes, fisheries, marine noise, deep biosphere, chemosynthetic ecology.

EMSO ERIC

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The Preparatory Phase of EMSO was funded by the European Seventh Framework Programme (FP7), involving 12 countries of the European area (Italy, France, Germany, Ireland, Spain, Sweden, Greece, UK, Norway, Portugal, Turkey, the Netherlands), and Romania (through GeoEcoMar), that has been involved as external interested country from 2010. The Preparatory Phase prepared the foundation for the adoption of the ERIC (European Research Infrastructure Consortium), that is the legal entity in charge of coordinating and facilitating access to these nodes of open ocean fixed point observatory distributed infrastructure.

EMSO ERIC is the central point of contact for observatory initiatives in other parts of the world to set up and promote cooperation in this field. EMSO ERIC integrates research, training, and information dissemination activities for ocean observatory nodes in Europe and enables scientists and other stakeholders to make efficient use of the EMSO distributed infrastructure around Europe.

EMSO Partners

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List of projects

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List of projects
Project Full name Year Funding Lead Details Outcome
ABEL Abyssal BEnthic Laboratory 1990-1993 FP3-MAST2 Tecnomare M. Berta et al.

Abyssal BEnthic Laboratory (ABEL): a novel approach for long-term investigation at abyssal depths, Journal of Marine Systems, Volume 6, Issue 3, 1995, Pages 211-225, ISSN 0924-7963

Feasibility and financial study aimed at identifying the scientific

requirements, possible technological solutions and opportunities for the development of an Abyssal BEnthic Laboratory

DESIBEL Deep-Sea Intervention on future BEnthic Laboratory 1990-1993 FP3-MAST2 IFREMER https://cordis.europa.eu/project/id/MAS20082

"New methods for deep sea intervention on benthic laboratories". DESIBEL project. Final results, comparisons of concepts and at sea validation

V. Rigaud et al. IEEE Oceanic Engineering Society. OCEANS'98. Conference Proceedings (Cat. No.98CH36259)

Feasibility study aimed at investigating methods for deployment and intervention on future benthic stations
GEOSTAR GEophysical and Oceanographic STation for Abyssal Research 1995-1998 FP4-MAST3 INGV https://cordis.europa.eu/project/id/MAS3950007 Realization of a multidisciplinary observatory for deep-sea application
ALIPOR Autonomous Lander Instrument Packages for Oceanographic Research 1996-1999 FP4-MAST3 University of Aberdeen https://cordis.europa.eu/project/id/MAS3950010 Autonomous landers that can conduct experiments and gather data on the sea floor have the potential to revolutionise oceanographic research. By using a number of landers, the spatial and temporal coverage of a single ship can be increased by orders of magnitude. Joint experiments in the Porcupine zone with FP4 – MAST3 BENGAL project.
GEOSTAR 2 GEophysical and Oceanographic STation for Abyssal Research 2nd phase: Deep-sea Scientific Mission 1999-2001 FP4-MAST3 INGV https://archimer.ifremer.fr/doc/00061/17268/14778.pdf Deep-sea mission of the observatory realized in the GEOSTAR project. Underwater volcano Massili north of Sicily.
ASSEM Array of sensors for long term seabed monitoring of geohazards 2002-2004 FP5-EESD IFREMER https://cordis.europa.eu/project/id/EVK3-CT-2001-00051

https://archimer.ifremer.fr/doc/00061/17272/14782.pdf

The project developed an underwater network for shallow waters (600 m w.d.) able to communicate in two ways with the land through a surface buoy acoustically linked with the underwater systems. Experiment in Gulf of Corinth and Norwegian Fjord.

ORION-GEOSTAR-3 Ocean Research by Integrated Observation Networks 2002-2005 FP5-EESD INGV https://cordis.europa.eu/project/id/EVK3-CT-2001-00067

http://www.moist.it/projects/orion-geostar3/4

https://archimer.ifremer.fr/doc/00061/17268/14778.pdf

The project represented the passage from a single node to a constellation, and realized a deep-water network able to communicate in underwater via acoustics with a main node and this main to communicate always via acoustics with a relay surface buoy linked to land via radio and satellite. ORION realized one of the first example of a near-real-time deep-sea network. Experiment in Gulf of Corinth.
ESONET-CA European Seafloor Observatory Network-Concerted Action 2002-2004 FP5 University of Aberdeen http://www.abdn.ac.uk/ecosystem/esonet http://www.esonet-noe.org/Associated-projects/ESONET-CA Assessment of European capability in ocean observatories

Site identification, technological issues.

EXOCET/D EXtreme ecosystem studies in the deep OCEan:Technological Developments 2004-2006 FP6-SUSTDEV IFREMER https://cordis.europa.eu/project/id/505342 Technological development of a specific instrumentation allowing the study of natural or accidentally perturbed ecosystems found in the deep ocean. Experiment in MoMar Azores site.
ESONIM European Seafloor Observatories Implementation Model 2004-2007 FP6 Marine Institute http://www.esonet-noe.org/Associated-projects/ESONIM Case study on Porcupine Abyssal Plain site to investigate legal and financial aspects and develop a Business Plan.
NEAREST Integrated Observations from NEAR shore SourcES of Tsunamis: toward an early warning system 2006-2010 FP6 CNR http://nearest.bo.ismar.cnr.it/documentation NEAREST activities included land investigations in areas of Portugal affected in the past by run-up of tsunamis, inundation maps, oceanographic campaigns for defining specific and reliable velocity models to be used in earthquake localizations, 1-year OBS campaign to detect seismic activity. In particular, INGV was in charge of the deposition for almost 2 years in near-source area in the Gulf of Cadiz at over 3200 m w.d. of a GEOSTAR-type multidisciplinary observatory, specifically enhanced with a prototypal system of Tsunami Early Warning.
ESONET-NoE European Seafloor Observatory Network-Network of Excellence 2007-2011 FP6-SUSTDEV IFREMER https://cordis.europa.eu/project/id/36851

http://www.esonet-noe.org/

Integration of the scientific/technological “Observatory Science” Community. Demonstration missions in Haakon Mosby mud volcano, Arctic Ocean Fram Strait, Porcupine Abyssal Plain, Momar Azores, West Ionian Sea, Gulf of Cadiz, Marmara Sea, Ligurian Sea.
EuroSITES Integration and enhancement of key existing European deep-ocean observatories 2008-2011 FP7 - Environment NERC Ehttps://cordis.europa.eu/project/id/202955/ Water-column observatories in Europe, related to OceanSites. Building agreed methods to collect time series of basic variables and common data protocols for real time and delayed mode observation. Complete ocean observatory data management system.
ENVRI Common Operations of Environmental Research Infrastructures 2011-2014 FP7 Amsterdam University https://cordis.europa.eu/project/id/283465 The project aimed at pursuing solutions and defining guidelines for the commonalities of ESFRI environmental research infrastructures.
EMSO-PP European Multidisciplinary Seafloor and water-column Observatory-Preparatory Phase 2008-2012 FP7-Infrastructures INGV https://cordis.europa.eu/project/id/211816 Development of the management structure: legal, governance and financial issues.
HYPOX In-situ monitoring of oxygen depletion in hypoxic ecosystems of coastal and open seas, and land-locked water bodies 2009-2012 FP7 Max Planck Institute for Marine Microbiology https://cordis.europa.eu/project/id/226213/reporting The project had as the main goal to increase in-situ monitoring systems for oxygen depletion in hypoxic ecosystems of coastal and open seas, and land-locked water bodies (such as lagoons) to better understand the global change effects on this phenomenon.
MARSITE New Directions in Seismic Hazard Assessment through Focused Earth Observation in the Marmara Supersite 2012-2015 FP7-Supersites KOERI-Kandilli Observatory https://cordis.europa.eu/project/id/308417/reporting

www.marsite.eu

The project included several research groups with different scientific background (from seismology to engineering, from geophysics to geochemistry) in multidisciplinary monitoring activities in the Marmara Sea (considered a Supersite for the seismology).
Fix Fixed Point Open Ocean Observatories 2013-2017 FP7-Infrastructures NERC https://cordis.europa.eu/project/id/312463

http://www.fixo3.eu/

Enhanced access to broad range of data and infrastructure

Coordination among observatories

COOPEUS Connecting Research Infrastructures. Strengthening the cooperation between the US and the EU in the field of environmental research infrastructures 2012-2015 FP7 MARUM-Bremen University https://cordis.europa.eu/project/id/312118/reporting The project aimed at implementing a sustainable cooperation between Europe and USA in the field of the environmental infrastructures, putting into relation homologous infrastructures to develop common policies, interoperability and synergies.
EMSODEV EMSO implementation and operation: DEVelopment of instrument module 2015-2019 H2020-EU.1.4.1.1. INGV http://www.emsodev.eu/deliverables.html

https://cordis.europa.eu/project/id/676555/reporting

EMSODEV is focused on development of EGIMs (EMSO Generic Instrument Modules) to ensure increased coordination, integration, interoperability and standardization across sites and disciplines, and of a DMP (Data Management Platform) to guarantee the data accessibility to the scientific users and stakeholders.
ENVRI-PLUS supporting environmental research with integrated solutions 2015-2019 H2020 Helsinki University, then ICOS ERIC https://www.envriplus.eu/

https://www.envriplus.eu/deliverables/

ENVRI-PLUS was a cluster of research infrastructures (RIs) for Environmental and Earth System sciences, built around ESFRI roadmap and associating leading e-infrastructures and Integrating Activities together with technical specialist partners. It included a marine domain where EMSO played a key role.
COOP+ (or COOP_PLUS) Cooperation of Research Infrastructures to address global challenges in the environmental field 2016-2019 H2020 Cordoba University http://www.coop-plus.eu/documents

https://cordis.europa.eu/project/id/654131

The general goal was to strengthen the links and coordination of the European RIs related to Marine Science (EMSO), Arctic and Atmospheric Research (EISCAT), Carbon Observation (ICOS) and Biodiversity (LifeWatch) with international counterparts (NEON, TERN, AMISR/SRI, CGSM, OOI, INPA/LBA, IMOS, ONC, AMERIFLUX, etc.) and to leverage international scientific cooperation and data exchange with non-EU countries.
DANUBIUS-PP PREPARATORY PHASE FOR THE PAN-EUROPEAN RESEARCH INFRASTRUCTURE DANUBIUS–RI “THE INTERNATIONAL CENTRE FOR ADVANCED STUDIES ON RIVER-SEA SYSTEMS 2016-2019 H2020-EU.1.4.1.1. INSTITUTUL NATIONAL DE CERCETARE-DEZVOLTARE PENTRU GEOLOGIE SI GEOECOLOGIE MARINA-GEOECOMAR https://danubius-pp.eu/ DANUBIUS-PP is a three-year project to raise DANUBIUS-RI (International Centre for Advanced Studies on River-Sea Systems) to the legal, financial and technical maturity required for successful implementation and development. DANUBIUS-RI is a pan-European distributed research infrastructure (RI) building on existing expertise to support interdisciplinary research on river-sea (RS) systems, spanning the environmental, social and economic sciences.
EMSO-Link Implementation of the Strategy to ensure the EMSO ERIC Long-term Sustainability 2017-2020 H2020-EU.1.4.1.1 EMSO ERIC https://cordis.europa.eu/project/id/731036/reporting Underpins the long-term sustainability of EMSO. Structure developed. SLAs signed. Services defined.
ENVRI-FAIR ENVironmental Research Infrastructures building Fair services Accessible for society, Innovation and Research 2019-2023 H2020-INFRAEOSC FZJ - IAGOS https://envri.eu/home-envri-fair/ The overarching goal is that at the end of the project, all participating Research Infrastructures have built a set of FAIR data services which enhances the efficiency and productivity of researchers, supports innovation, enables data- and knowledge-based decisions and connects the ENVRI Cluster to the EOSC
ENRIITC European Network of Research Infrastructures & IndusTry for Collaboration 2020-2023 H2020-EU.1.4.2.1 EUROPEAN SPALLATION SOURCE ERIC https://enriitc.eu/ It will build a permanent network of Industrial Liaison and Contact Officers (ILOs and ICOs) to maximise their engagement and boost the research infrastructures-industry partnerships.
EurofleetsPlus An alliance of European marine research infrastructure to meet the evolving needs of the research and industrial communities. 2019-2023 H2020-EU.1.4.1.2. MARINE INSTITUTE https://www.eurofleets.eu/ EurofleetsPlus will facilitate open access to an integrated and advanced research vessel fleet, designed to meet the evolving and challenging needs of the user community. European and international researchers from academia and industry will be able to apply for several access programmes, through a single-entry system.

References

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  1. ^ "This page is the home page of the RI website - Research Infrastructures - Research - European Commission". Ec.europa.eu. Retrieved 2023-02-13.
  2. ^ Paolo Favali, and Laura Beranzoli. "EMSO: European multidisciplinary seafloor observatory." Nuclear Instruments and Methods in Physics Research Section A: Accelerators, Spectrometers, Detectors and Associated Equipment 602.1 (2009): 21-27.
  3. ^ Exploring the last great frontier Archived 2014-02-22 at the Wayback Machine, Projects Magazine, Issue 10, p. 79-81
  4. ^ Favali, P., Beranzoli, L., D’Anna, G., Gasparoni, F., Marvaldi, J., Clauss, G., Gerber, H.W., Nicot, M., Marani, M.P., Gamberi, F., Millot, C., Flueh, E.R., 2006a. A fleet of multiparameter observatories for geophysical and environmental monitoring at seafloor. Annals of Geophysics 49, 659–680
  5. ^ "Understanding the mysteries of the oceans". Projects Magazine. pp. 79–84. Retrieved 2014-02-14.
  6. ^ "Galway Statement on Atlantic Ocean Cooperation" (PDF). Ec.europa.eu. Retrieved 2014-02-14.
  7. ^ "Challenge". Igfagcr.org. Retrieved 2014-02-14.
  8. ^ "Coopeus". Coopeus.eu. Retrieved 2014-02-14.
  9. ^ Ruhl, Henry A., et al. "Societal need for improved understanding of climate change, anthropogenic impacts, and geo-hazard warning drive development of ocean observatories in European Seas." Progress in Oceanography 91.1 (2011): 1-33.
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