Abstract
Cold-water corals (CWCs) thrive in areas with complex and rough topography favoring the development of highly diverse benthic communities. Several biotic and abiotic factors including organic matter supply, temperature, bottom roughness and currents are important drivers of ecosystem structure and functioning in deep-sea environments at different spatial and temporal scales. Little is known, however, how basin-scale changes in the ocean climate affect these drivers at local scales. Here, we use high-resolution implementations of the hydrodynamic model ROMS-AGRIF for estimating characteristic spatial and temporal scales of local hydrodynamics in response to variations of basin-scale currents imposed by distinct changes of the Atlantic Meridional Overturning Circulation (AMOC) in the past century. We focus on two CWC communities on the SE Rockall Bank slope and at Condor Seamount. We considered two contrasting AMOC states that were identified from the 1958–2009 hindcast of the 1/20° resolution VIKING20 North Atlantic basin-scale ocean circulation model and used as boundary conditions for the high-resolution local area models. At SE Rockall Bank, variability of near-bottom currents in both regions was largely dominated by tidal dynamics, but strongly modified by AMOC induced basin-scale variations of water mass properties and bottom currents. During strong AMOC years, waters in the main CWC depth corridor (600–1200 m) were cooler and less saline but were dominated by stronger bottom currents when compared with conditions during weak AMOC years. At Condor Seamount, bottom currents were largely unaffected by AMOC related changes close to the summit at water depths < 400 m. Kinetic energy dissipation rates derived from the 3D near-bottom velocity field appeared to positively relate with the in-situ CWC distribution. Kinetic energy dissipation is therefore proposed as a mechanistic descriptor of CWC presence as it provides a more mechanistic view of hydrodynamics driving organic matter supply to filter and suspension-feeding communities.
| Originalsprog | Engelsk |
|---|---|
| Artikelnummer | 103031 |
| Tidsskrift | Progress in Oceanography |
| Vol/bind | 214 |
| Antal sider | 19 |
| ISSN | 0079-6611 |
| DOI | |
| Status | Udgivet - jun. 2023 |
Bibliografisk note
Funding Information:This study has received funding from the European Union's Horizon 2020 Research and Innovation Programme under grant agreement nos. 678760 (ATLAS) and 818123 (iAtlantic). The output of this study reflects only the author’s view, and the European Union cannot be held responsible for any use that may be made of the information contained therein. We acknowledge funding of the Netherlands Organisation for Scientific Research NWO and Royal Netherlands Institute for Sea Research NIOZ in organising the Netherlands Initiative Changing Oceans NICO expedition in 2018. This research was partially funded by the Netherlands Organisation for Scientific Research (VIDI grant 864.13.007). T.M. and M.C.S. were supported by the FCT-IP Stimulus of Scientific Employment Program (CCCIND/03345/2020 and CCCIND/03346/2020, respectively). C.D.-C. was supported by the FCT-IP Project UIDP/05634/2020. M.C.S., C.D.-C. and T.M. also acknowledge funds through the FCT – Foundation for Science and Technology, I.P. under the project OKEANOS UIDB/05634/2020 and UIDP/05634/2020 and through the FCT Regional Government of the Azores under the project M1.1.A/REEQ.CIENTÍFICO UI&D/2021/010.
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© 2023 The Author(s)