Estimating seabed pressure from demersal trawls, seines, and dredges based on gear design and dimensions

Ole Ritzau Eigaard; Francois Bastardie; Mike Breen; Grete E. Dinesen; Niels T. Hintzen; Pascal Lafargue; Lars Olof Mortensen; J. Rasmus Nielsen; Hans C. Nilson; Finbarr G. O'Neil; Hans Polet; David G. Reid; Antonello Sala; Mattias Sköld; Chris Smith; Thomas Kirk Sørensen; Oliver Tully; Mustafa Zenging; Adriaan D. Rijnsdorp

doi:10.1093/icesjms/fsv099

Estimating seabed pressure from demersal trawls, seines, and dredges based on gear design and dimensions

Ole Ritzau Eigaard
, Francois Bastardie
, Mike Breen
, Grete E. Dinesen
, Niels T. Hintzen
, Pascal Lafargue
, Lars Olof Mortensen
, J. Rasmus Nielsen
, Hans C. Nilson
, Finbarr G. O'Neil
, Hans Polet
, David G. Reid
, Antonello Sala
, Mattias Sköld
, Chris Smith
, Thomas Kirk Sørensen
, Oliver Tully
, Mustafa Zenging
, Adriaan D. Rijnsdorp

Institute of Marine Research
Swedish University of Agricultural Sciences
Marine Scotland Science
Marine Institute
National Research Council of Italy
Hellenic Centre for Marine Research
Central Fisheries Research Institute
Wageningen University & Research
Institut français de recherche pour l'exploitation de la mer
Research Institute for Agriculture and Fisheries

Research output: Contribution to journal › Journal article › Research › peer-review

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Abstract

This study assesses the seabed pressure of towed fishing gears and models the physical impact (area and depth of seabed penetration) from trip-based information of vessel size, gear type, and catch. Traditionally fishing pressures are calculated top-down by making use of large-scale statistics such as logbook data. Here, we take a different approach starting from the gear itself (design and dimensions) to estimate the physical interactions with the seabed at the level of the individual fishing operation. We defined 14 distinct towed gear groups in European waters (eight otter trawl groups, three beam trawl groups, two demersal seine groups, and one dredge group), for which we established gear “footprints”. The footprint of a gear is defined as the relative contribution from individual larger gear components, such as trawl doors, sweeps, and groundgear, to the total area and severity of the gear's impact. An industry-based survey covering 13 countries provided the basis for estimating the relative impact-area contributions from individual gear components, whereas sediment penetration was estimated based on a literature review. For each gear group, a vessel size–gear size relationship was estimated to enable the prediction of gear footprint area and sediment penetration from vessel size. Application of these relationships with average vessel sizes and towing speeds provided hourly swept-area estimates by métier. Scottish seining has the largest overall gear footprint of ∼1.6 km2 h−1 of which 0.08 km2 has an impact at the subsurface level (sediment penetration ≥ 2 cm). Beam trawling for flatfish ranks low when comparing overall footprint size/hour but ranks substantially higher when comparing only impact at the subsurface level (0.19 km2h−1). These results have substantial implications for the definition, estimation, and monitoring of fishing pressure indicators, which are discussed in the context of an ecosystem approach to fisheries management

Original language	English
Journal	ICES Journal of Marine Science
Volume	73
Issue number	Suppl. 1
Pages (from-to)	27-43
ISSN	1054-3139
DOIs	https://doi.org/10.1093/icesjms/fsv099
Publication status	Published - 2016

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http://icesjms.oxfordjournals.org/content/early/2015/06/08/icesjms.fsv099.full.pdf+html

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Eigaard, O. R., Bastardie, F., Breen, M., Dinesen, G. E., Hintzen, N. T., Lafargue, P., Mortensen, L. O., Nielsen, J. R., Nilson, H. C., O'Neil, F. G., Polet, H., Reid, D. G., Sala, A., Sköld, M., Smith, C., Sørensen, T. K., Tully, O., Zenging, M., & Rijnsdorp, A. D. (2016). Estimating seabed pressure from demersal trawls, seines, and dredges based on gear design and dimensions. ICES Journal of Marine Science, 73(Suppl. 1), 27-43. https://doi.org/10.1093/icesjms/fsv099

@article{13e1a209ecb7484ca0fc7163e07a6ea3,

title = "Estimating seabed pressure from demersal trawls, seines, and dredges based on gear design and dimensions",

abstract = "This study assesses the seabed pressure of towed fishing gears and models the physical impact (area and depth of seabed penetration) from trip-based information of vessel size, gear type, and catch. Traditionally fishing pressures are calculated top-down by making use of large-scale statistics such as logbook data. Here, we take a different approach starting from the gear itself (design and dimensions) to estimate the physical interactions with the seabed at the level of the individual fishing operation. We defined 14 distinct towed gear groups in European waters (eight otter trawl groups, three beam trawl groups, two demersal seine groups, and one dredge group), for which we established gear “footprints”. The footprint of a gear is defined as the relative contribution from individual larger gear components, such as trawl doors, sweeps, and groundgear, to the total area and severity of the gear's impact. An industry-based survey covering 13 countries provided the basis for estimating the relative impact-area contributions from individual gear components, whereas sediment penetration was estimated based on a literature review. For each gear group, a vessel size–gear size relationship was estimated to enable the prediction of gear footprint area and sediment penetration from vessel size. Application of these relationships with average vessel sizes and towing speeds provided hourly swept-area estimates by m{\'e}tier. Scottish seining has the largest overall gear footprint of ∼1.6 km2 h−1 of which 0.08 km2 has an impact at the subsurface level (sediment penetration ≥ 2 cm). Beam trawling for flatfish ranks low when comparing overall footprint size/hour but ranks substantially higher when comparing only impact at the subsurface level (0.19 km2h−1). These results have substantial implications for the definition, estimation, and monitoring of fishing pressure indicators, which are discussed in the context of an ecosystem approach to fisheries management",

author = "Eigaard, \{Ole Ritzau\} and Francois Bastardie and Mike Breen and Dinesen, \{Grete E.\} and Hintzen, \{Niels T.\} and Pascal Lafargue and Mortensen, \{Lars Olof\} and Nielsen, \{J. Rasmus\} and Nilson, \{Hans C.\} and O'Neil, \{Finbarr G.\} and Hans Polet and Reid, \{David G.\} and Antonello Sala and Mattias Sk{\"o}ld and Chris Smith and S{\o}rensen, \{Thomas Kirk\} and Oliver Tully and Mustafa Zenging and Rijnsdorp, \{Adriaan D.\}",

year = "2016",

doi = "10.1093/icesjms/fsv099",

language = "English",

volume = "73",

pages = "27--43",

journal = "ICES Journal of Marine Science",

issn = "1054-3139",

publisher = "Oxford University Press",

number = "Suppl. 1",

}

Eigaard, OR , Bastardie, F, Breen, M, Dinesen, GE, Hintzen, NT, Lafargue, P, Mortensen, LO, Nielsen, JR, Nilson, HC, O'Neil, FG, Polet, H, Reid, DG, Sala, A, Sköld, M, Smith, C, Sørensen, TK, Tully, O, Zenging, M & Rijnsdorp, AD 2016, 'Estimating seabed pressure from demersal trawls, seines, and dredges based on gear design and dimensions', ICES Journal of Marine Science, vol. 73, no. Suppl. 1, pp. 27-43. https://doi.org/10.1093/icesjms/fsv099

TY - JOUR

T1 - Estimating seabed pressure from demersal trawls, seines, and dredges based on gear design and dimensions

AU - Eigaard, Ole Ritzau

AU - Bastardie, Francois

AU - Breen, Mike

AU - Dinesen, Grete E.

AU - Hintzen, Niels T.

AU - Lafargue, Pascal

AU - Mortensen, Lars Olof

AU - Nielsen, J. Rasmus

AU - Nilson, Hans C.

AU - O'Neil, Finbarr G.

AU - Polet, Hans

AU - Reid, David G.

AU - Sala, Antonello

AU - Sköld, Mattias

AU - Smith, Chris

AU - Sørensen, Thomas Kirk

AU - Tully, Oliver

AU - Zenging, Mustafa

AU - Rijnsdorp, Adriaan D.

PY - 2016

Y1 - 2016

N2 - This study assesses the seabed pressure of towed fishing gears and models the physical impact (area and depth of seabed penetration) from trip-based information of vessel size, gear type, and catch. Traditionally fishing pressures are calculated top-down by making use of large-scale statistics such as logbook data. Here, we take a different approach starting from the gear itself (design and dimensions) to estimate the physical interactions with the seabed at the level of the individual fishing operation. We defined 14 distinct towed gear groups in European waters (eight otter trawl groups, three beam trawl groups, two demersal seine groups, and one dredge group), for which we established gear “footprints”. The footprint of a gear is defined as the relative contribution from individual larger gear components, such as trawl doors, sweeps, and groundgear, to the total area and severity of the gear's impact. An industry-based survey covering 13 countries provided the basis for estimating the relative impact-area contributions from individual gear components, whereas sediment penetration was estimated based on a literature review. For each gear group, a vessel size–gear size relationship was estimated to enable the prediction of gear footprint area and sediment penetration from vessel size. Application of these relationships with average vessel sizes and towing speeds provided hourly swept-area estimates by métier. Scottish seining has the largest overall gear footprint of ∼1.6 km2 h−1 of which 0.08 km2 has an impact at the subsurface level (sediment penetration ≥ 2 cm). Beam trawling for flatfish ranks low when comparing overall footprint size/hour but ranks substantially higher when comparing only impact at the subsurface level (0.19 km2h−1). These results have substantial implications for the definition, estimation, and monitoring of fishing pressure indicators, which are discussed in the context of an ecosystem approach to fisheries management

AB - This study assesses the seabed pressure of towed fishing gears and models the physical impact (area and depth of seabed penetration) from trip-based information of vessel size, gear type, and catch. Traditionally fishing pressures are calculated top-down by making use of large-scale statistics such as logbook data. Here, we take a different approach starting from the gear itself (design and dimensions) to estimate the physical interactions with the seabed at the level of the individual fishing operation. We defined 14 distinct towed gear groups in European waters (eight otter trawl groups, three beam trawl groups, two demersal seine groups, and one dredge group), for which we established gear “footprints”. The footprint of a gear is defined as the relative contribution from individual larger gear components, such as trawl doors, sweeps, and groundgear, to the total area and severity of the gear's impact. An industry-based survey covering 13 countries provided the basis for estimating the relative impact-area contributions from individual gear components, whereas sediment penetration was estimated based on a literature review. For each gear group, a vessel size–gear size relationship was estimated to enable the prediction of gear footprint area and sediment penetration from vessel size. Application of these relationships with average vessel sizes and towing speeds provided hourly swept-area estimates by métier. Scottish seining has the largest overall gear footprint of ∼1.6 km2 h−1 of which 0.08 km2 has an impact at the subsurface level (sediment penetration ≥ 2 cm). Beam trawling for flatfish ranks low when comparing overall footprint size/hour but ranks substantially higher when comparing only impact at the subsurface level (0.19 km2h−1). These results have substantial implications for the definition, estimation, and monitoring of fishing pressure indicators, which are discussed in the context of an ecosystem approach to fisheries management

U2 - 10.1093/icesjms/fsv099

DO - 10.1093/icesjms/fsv099

M3 - Journal article

SN - 1054-3139

VL - 73

SP - 27

EP - 43

JO - ICES Journal of Marine Science

JF - ICES Journal of Marine Science

IS - Suppl. 1

ER -

Estimating seabed pressure from demersal trawls, seines, and dredges based on gear design and dimensions

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