Modelling of interactions between inshore and offshore aquaculture

Offshore aquaculture is the subject of intense debate, focusing on feasibility, sustainability, and the potential for effective expansion in the context of competing uses of the coastal zone, and a world requirement for an additional thirty million tonnes of aquatic products by 2050. A modelling fra...

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Bibliographic Details
Published inAquaculture Vol. 426-427; pp. 154 - 164
Main Authors Ferreira, J.G., Saurel, C., Lencart e Silva, J.D., Nunes, J.P., Vazquez, F.
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 20.04.2014
Elsevier Sequoia S.A
Subjects
Aquaculture
biomass
biosecurity
bream
cage culture
capital
case studies
clams
coasts
computer software
dynamic models
Ecological model
Ecosystem Approach to Aquaculture
ecosystems
fisheries
food availability
FORWARD
governance
hydrodynamics
income
Integrated Coastal Zone Management
Integrated Multi-Trophic Aquaculture (IMTA)
leasing
Mollusks
mussels
Mytilus galloprovincialis
nitrogen
nutrients
parks
phosphorus
planning
Portugal
prices
primary productivity
risk
shellfish
Simulation
Soil and Water Assessment Tool model
Sparus aurata
stakeholders
stocking rate
Sustainability
wastewater treatment
Watersheds
Portugal
FORWARD
Integrated Coastal Zone Management
Integrated Multi-Trophic Aquaculture (IMTA)
Sustainability
Ecological model
Ecosystem Approach to Aquaculture
Online AccessGet full text
ISSN0044-8486
1873-5622
DOI10.1016/j.aquaculture.2014.01.030

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Abstract Offshore aquaculture is the subject of intense debate, focusing on feasibility, sustainability, and the potential for effective expansion in the context of competing uses of the coastal zone, and a world requirement for an additional thirty million tonnes of aquatic products by 2050. A modelling framework that integrates the SWAT model for the watershed, Delft3D for ocean circulation, and the EcoWin model for long-term (10year) ecological simulations, was developed for integrated analysis of catchment, inshore waters, and offshore aquaculture, providing an approach that addresses production, environmental effects, and disease interactions. This framework was tested using a case study in SE Portugal, for a system-scale modelling domain with an ocean area of 470km2 and a coastal watershed area of 627km2. This domain contains an inshore area of 184km2 (Ria Formosa) subject to multiple (often conflicting) uses, including aquaculture of the high value (farmgate price>10€kg−1) clam Tapes decussatus, and one of the first offshore aquaculture parks in the world, located at distance of 3.6nm from the coast, at a water depth of 30–60m, with an area of 15km2. The park contains 60 leases, of which at most 70% are for finfish cage culture, and at least 30% for bivalve longline culture. A substantial part of the dissolved nutrients required to drive primary production that constitutes the food source for clams originates from the coastal catchment. Although stakeholder perception is that nutrients are mainly linked to point-source discharges from wastewater treatment plants, watershed modelling indicates that 55% of the nitrogen and 70% of the phosphorus loads are from diffuse sources. The residence time of waters in the inshore area is low (1–2days), and consequently pelagic primary production takes place offshore, and drives inshore clam production. The longline culture of Mediterranean mussels (Mytilus galloprovincialis) in the offshore park reduces inshore food availability for clams: simulations suggest that a 3% decrease in clam yields will occur due to offshore mussel cultivation, at a cost of 1.2million€. This is offset by revenue from offshore culture, but is a source of stakeholder conflict. Potential disease spread between the offshore and inshore systems was analysed using a particle tracking model, and allowed the development of a risk exposure map. This illustrates the challenges posed by hydrodynamic connectivity with respect to biosecurity of aquaculture and fisheries, both inshore and offshore. The model framework was also used for optimisation of stocking density, and analysis of combined culture of finfish and shellfish, both in terms of production and environmental effects. In the offshore aquaculture park, the models suggest that integrated multi-trophic aquaculture (IMTA) of gilthead bream (Sparus aurata) and Mediterranean mussels allows for an increased harvestable biomass of mussels, particularly at higher stocking densities, and offsets some of the negative externalities of finfish culture. By quantifying issues such as reduced yields for inshore stakeholders due to offshore activity, and illustrating the need for strong governance to offset disease risks, dynamic models make a valuable contribution in assessing the feasibility of offshore aquaculture, and the general principles that should underpin licensing and regulation of this sector. We stress the need to go beyond the conventional spatial planning toolset in order to ensure an ecosystem approach to aquaculture, and the opportunities that exist for applying a systems framework in an information economy, where the capital costs of software and data have been sharply reduced. •Dynamic modelling framework simulates inshore and offshore aquaculture interactions.•Integrated Multi-Trophic Aquaculture (IMTA) shows enhanced shellfish yields.•Finfish and bivalve IMTA in offshore conditions shows a reduction in organic loading.•Offshore shellfish production in SE Portugal impacts inshore yields.•Hydrodynamic connectivity models can produce risk analysis maps for disease control.
AbstractList Offshore aquaculture is the subject of intense debate, focusing on feasibility, sustainability, and the potential for effective expansion in the context of competing uses of the coastal zone, and a world requirement for an additional thirty million tonnes of aquatic products by 2050. A modelling framework that integrates the SWAT model for the watershed, Delft3D for ocean circulation, and the EcoWin model for long-term (10 year) ecological simulations, was developed for integrated analysis of catchment, inshore waters, and offshore aquaculture, providing an approach that addresses production, environmental effects, and disease interactions. This framework was tested using a case study in SE Portugal, for a system-scale modelling domain with an ocean area of 470 km2 and a coastal watershed area of 627 km2. This domain contains an inshore area of 184 km2 (Ria Formosa) subject to multiple (often conflicting) uses, including aquaculture of the high value (farmgate price > 10 euro kg^sup -1^) clam Tapes decussatus, and one of the first offshore aquaculture parks in the world, located at distance of 3.6 nm from the coast, at a water depth of 30-60 m, with an area of 15 km2. The park contains 60 leases, of which at most 70% are for finfish cage culture, and at least 30% for bivalve longline culture. A substantial part of the dissolved nutrients required to drive primary production that constitutes the food source for clams originates from the coastal catchment. Although stakeholder perception is that nutrients are mainly linked to point-source discharges from wastewater treatment plants, watershed modelling indicates that 55% of the nitrogen and 70% of the phosphorus loads are from diffuse sources. The residence time of waters in the inshore area is low (1-2 days), and consequently pelagic primary production takes place offshore, and drives inshore clam production. The longline culture of Mediterranean mussels (Mytilus galloprovincialis) in the offshore park reduces inshore food availability for clams: simulations suggest that a 3% decrease in clam yields will occur due to offshore mussel cultivation, at a cost of 1.2 million euro. This is offset by revenue from offshore culture, but is a source of stakeholder conflict. Potential disease spread between the offshore and inshore systems was analysed using a particle tracking model, and allowed the development of a risk exposure map. This illustrates the challenges posed by hydrodynamic connectivity with respect to biosecurity of aquaculture and fisheries, both inshore and offshore. The model framework was also used for optimisation of stocking density, and analysis of combined culture of finfish and shellfish, both in terms of production and environmental effects. In the offshore aquaculture park, the models suggest that integrated multi-trophic aquaculture (IMTA) of gilthead bream (Sparus aurata) and Mediterranean mussels allows for an increased harvestable biomass of mussels, particularly at higher stocking densities, and offsets some of the negative externalities of finfish culture. By quantifying issues such as reduced yields for inshore stakeholders due to offshore activity, and illustrating the need for strong governance to offset disease risks, dynamic models make a valuable contribution in assessing the feasibility of offshore aquaculture, and the general principles that should underpin licensing and regulation of this sector. We stress the need to go beyond the conventional spatial planning toolset in order to ensure an ecosystem approach to aquaculture, and the opportunities that exist for applying a systems framework in an information economy, where the capital costs of software and data have been sharply reduced. [PUBLICATION ABSTRACT]
Offshore aquaculture is the subject of intense debate, focusing on feasibility, sustainability, and the potential for effective expansion in the context of competing uses of the coastal zone, and a world requirement for an additional thirty million tonnes of aquatic products by 2050. A modelling framework that integrates the SWAT model for the watershed, Delft3D for ocean circulation, and the EcoWin model for long-term (10year) ecological simulations, was developed for integrated analysis of catchment, inshore waters, and offshore aquaculture, providing an approach that addresses production, environmental effects, and disease interactions. This framework was tested using a case study in SE Portugal, for a system-scale modelling domain with an ocean area of 470km2 and a coastal watershed area of 627km2. This domain contains an inshore area of 184km2 (Ria Formosa) subject to multiple (often conflicting) uses, including aquaculture of the high value (farmgate price>10€kg−1) clam Tapes decussatus, and one of the first offshore aquaculture parks in the world, located at distance of 3.6nm from the coast, at a water depth of 30–60m, with an area of 15km2. The park contains 60 leases, of which at most 70% are for finfish cage culture, and at least 30% for bivalve longline culture. A substantial part of the dissolved nutrients required to drive primary production that constitutes the food source for clams originates from the coastal catchment. Although stakeholder perception is that nutrients are mainly linked to point-source discharges from wastewater treatment plants, watershed modelling indicates that 55% of the nitrogen and 70% of the phosphorus loads are from diffuse sources. The residence time of waters in the inshore area is low (1–2days), and consequently pelagic primary production takes place offshore, and drives inshore clam production. The longline culture of Mediterranean mussels (Mytilus galloprovincialis) in the offshore park reduces inshore food availability for clams: simulations suggest that a 3% decrease in clam yields will occur due to offshore mussel cultivation, at a cost of 1.2million€. This is offset by revenue from offshore culture, but is a source of stakeholder conflict. Potential disease spread between the offshore and inshore systems was analysed using a particle tracking model, and allowed the development of a risk exposure map. This illustrates the challenges posed by hydrodynamic connectivity with respect to biosecurity of aquaculture and fisheries, both inshore and offshore. The model framework was also used for optimisation of stocking density, and analysis of combined culture of finfish and shellfish, both in terms of production and environmental effects. In the offshore aquaculture park, the models suggest that integrated multi-trophic aquaculture (IMTA) of gilthead bream (Sparus aurata) and Mediterranean mussels allows for an increased harvestable biomass of mussels, particularly at higher stocking densities, and offsets some of the negative externalities of finfish culture. By quantifying issues such as reduced yields for inshore stakeholders due to offshore activity, and illustrating the need for strong governance to offset disease risks, dynamic models make a valuable contribution in assessing the feasibility of offshore aquaculture, and the general principles that should underpin licensing and regulation of this sector. We stress the need to go beyond the conventional spatial planning toolset in order to ensure an ecosystem approach to aquaculture, and the opportunities that exist for applying a systems framework in an information economy, where the capital costs of software and data have been sharply reduced. •Dynamic modelling framework simulates inshore and offshore aquaculture interactions.•Integrated Multi-Trophic Aquaculture (IMTA) shows enhanced shellfish yields.•Finfish and bivalve IMTA in offshore conditions shows a reduction in organic loading.•Offshore shellfish production in SE Portugal impacts inshore yields.•Hydrodynamic connectivity models can produce risk analysis maps for disease control.
Offshore aquaculture is the subject of intense debate, focusing on feasibility, sustainability, and the potential for effective expansion in the context of competing uses of the coastal zone, and a world requirement for an additional thirty million tonnes of aquatic products by 2050.A modelling framework that integrates the SWAT model for the watershed, Delft3D for ocean circulation, and the EcoWin model for long-term (10year) ecological simulations, was developed for integrated analysis of catchment, inshore waters, and offshore aquaculture, providing an approach that addresses production, environmental effects, and disease interactions. This framework was tested using a case study in SE Portugal, for a system-scale modelling domain with an ocean area of 470km2 and a coastal watershed area of 627km2.This domain contains an inshore area of 184km2 (Ria Formosa) subject to multiple (often conflicting) uses, including aquaculture of the high value (farmgate price>10€kg−1) clam Tapes decussatus, and one of the first offshore aquaculture parks in the world, located at distance of 3.6nm from the coast, at a water depth of 30–60m, with an area of 15km2. The park contains 60 leases, of which at most 70% are for finfish cage culture, and at least 30% for bivalve longline culture.A substantial part of the dissolved nutrients required to drive primary production that constitutes the food source for clams originates from the coastal catchment. Although stakeholder perception is that nutrients are mainly linked to point-source discharges from wastewater treatment plants, watershed modelling indicates that 55% of the nitrogen and 70% of the phosphorus loads are from diffuse sources.The residence time of waters in the inshore area is low (1–2days), and consequently pelagic primary production takes place offshore, and drives inshore clam production. The longline culture of Mediterranean mussels (Mytilus galloprovincialis) in the offshore park reduces inshore food availability for clams: simulations suggest that a 3% decrease in clam yields will occur due to offshore mussel cultivation, at a cost of 1.2million€. This is offset by revenue from offshore culture, but is a source of stakeholder conflict.Potential disease spread between the offshore and inshore systems was analysed using a particle tracking model, and allowed the development of a risk exposure map. This illustrates the challenges posed by hydrodynamic connectivity with respect to biosecurity of aquaculture and fisheries, both inshore and offshore.The model framework was also used for optimisation of stocking density, and analysis of combined culture of finfish and shellfish, both in terms of production and environmental effects. In the offshore aquaculture park, the models suggest that integrated multi-trophic aquaculture (IMTA) of gilthead bream (Sparus aurata) and Mediterranean mussels allows for an increased harvestable biomass of mussels, particularly at higher stocking densities, and offsets some of the negative externalities of finfish culture.By quantifying issues such as reduced yields for inshore stakeholders due to offshore activity, and illustrating the need for strong governance to offset disease risks, dynamic models make a valuable contribution in assessing the feasibility of offshore aquaculture, and the general principles that should underpin licensing and regulation of this sector.We stress the need to go beyond the conventional spatial planning toolset in order to ensure an ecosystem approach to aquaculture, and the opportunities that exist for applying a systems framework in an information economy, where the capital costs of software and data have been sharply reduced.
Author Ferreira, J.G.
Vazquez, F.
Lencart e Silva, J.D.
Saurel, C.
Nunes, J.P.
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  organization: New University of Lisbon, Faculty of Sciences and Technology, Centre for Ocean and Environment (IMAR), DCEA, FCT, Qta Torre, 2829-516 Monte de Caparica, Portugal
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IngestDate Sun Sep 28 03:57:20 EDT 2025
Fri Jul 25 04:28:39 EDT 2025
Tue Jul 01 04:00:47 EDT 2025
Thu Apr 24 22:55:22 EDT 2025
Fri Feb 23 02:31:41 EST 2024
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Keywords FORWARD
Integrated Coastal Zone Management
Integrated Multi-Trophic Aquaculture (IMTA)
Sustainability
Ecological model
Ecosystem Approach to Aquaculture
Language English
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OpenAccessLink http://hdl.handle.net/10773/21894
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crossref_primary_10_1016_j_aquaculture_2014_01_030
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PublicationDate 2014-04-20
PublicationDateYYYYMMDD 2014-04-20
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  year: 2014
  text: 2014-04-20
  day: 20
PublicationDecade 2010
PublicationPlace Amsterdam
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PublicationTitle Aquaculture
PublicationYear 2014
Publisher Elsevier B.V
Elsevier Sequoia S.A
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Snippet Offshore aquaculture is the subject of intense debate, focusing on feasibility, sustainability, and the potential for effective expansion in the context of...
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SubjectTerms Aquaculture
biomass
biosecurity
bream
cage culture
capital
case studies
clams
coasts
computer software
dynamic models
Ecological model
Ecosystem Approach to Aquaculture
ecosystems
fisheries
food availability
FORWARD
governance
hydrodynamics
income
Integrated Coastal Zone Management
Integrated Multi-Trophic Aquaculture (IMTA)
leasing
Mollusks
mussels
Mytilus galloprovincialis
nitrogen
nutrients
parks
phosphorus
planning
Portugal
prices
primary productivity
risk
shellfish
Simulation
Soil and Water Assessment Tool model
Sparus aurata
stakeholders
stocking rate
Sustainability
wastewater treatment
Watersheds
Title Modelling of interactions between inshore and offshore aquaculture
URI https://dx.doi.org/10.1016/j.aquaculture.2014.01.030
https://www.proquest.com/docview/1519413009
https://www.proquest.com/docview/2000208065
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