EVIDENCE OF TRAWL-INDUCED RESUSPENSION AT THE WHITTARD CANYON, NE ATLANTIC?

A M Wilson1, Kostas Kiriakoulakis2, Robin Raine1, Hans D Gerritsen3, Sabena Blackbird4, A. Louise Allcock1 and Martin G White1, (1)National University of Ireland, Galway, Earth and Ocean Sciences, Ryan Institute and School of Natural Sciences, Galway, Ireland, (2)Liverpool John Moores University, School of Natural Sciences and Psychology, Liverpool, United Kingdom, (3)Marine Institute, Rinville, Oranmore, Co. Galway, Ireland, (4)University of Liverpool, School of Environmental Sciences, Liverpool, United Kingdom
Abstract:
Four research surveys (2011-2014) to the Whittard Canyon have taken place as part of an Irish Bio-discovery and Ecosystem functioning project. Hydrographic observations including turbidity measurements and samples for biogeochemical analysis were collected in order to improve our understanding of sediment transport, biogeochemical cycling and trophic food webs within canyons. Benthic and intermediate nepheloid layers were detected during all four surveys, in eastern and western branches of the canyon. These layers act as a pathway from productive shelf environments to the deep abyss. Unusual peaks in turbidity were detected in two branches of the canyon in June 2013. These turbidity peaks, termed Enhanced Nepheloid Layers (ENLs), had elevated suspended particulate matter concentrations exceeding ~1 mg L-1. Typically, concentrations of material in nepheloid layers range between 0.28-0.6 mg L-1, while the largest ENLs measured between ~2-8 mg L-1. The ENLs measured ~100-260 m in vertical height and were detected in water depths of between 640-2880 m. Vessel Monitoring System data showed that high spatial and temporal activity of potential bottom trawling vessels coincided with the occurrence of the ENLs. Molar C/N ratios of the suspended organic material from the ENLs showed a high degree of degradation. While trawling has previously been suspected to affect the Whittard Canyon, this is the first study to provide evidence of such activity. Regular occurrences of these events are likely to have implications for increased sediment fluxes, burial of organic carbon and alteration of benthic and canyon ecosystems.