Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China

Recirculating aquaculture systems (RAS) are an alternative technology to tackle the major environmental challenges associated with conventional cage culture systems. In order to systematically assess the environmental performance of RAS farming, it is important to take the whole life cycle into acco...

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Bibliographic Details
Published in:Journal of Industrial Ecology
Main Authors: Song, Xingqiang, Liu, Ying, Pettersen, Johan Berg, Brandao, Miguel, Ma, Xiaona, Roberg, Stian, Frostell, Bjorn
Format: Report
Language:English
Published: WILEY 2019
Subjects:
atlantic salmon
feed production
indoor aquaculture
industrial ecology
life cycle assessment (LCA)
recirculating aquaculture systems
Science & Technology - Other Topics
Engineering
Environmental Sciences & Ecology
Green & Sustainable Science & Technology
Environmental
Environmental Sciences
ENVIRONMENTAL-IMPACT
PERFORMANCE
WATER
Atlantic salmon
Online Access:http://ir.qdio.ac.cn/handle/337002/163436
https://doi.org/10.1111/jiec.12845
id ftchinacasciocas:oai:ir.qdio.ac.cn:337002/163436
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spelling ftchinacasciocas:oai:ir.qdio.ac.cn:337002/163436 2023-05-15T15:31:16+02:00 Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China Song, Xingqiang Liu, Ying Pettersen, Johan Berg Brandao, Miguel Ma, Xiaona Roberg, Stian Frostell, Bjorn 2019-10-01 http://ir.qdio.ac.cn/handle/337002/163436 https://doi.org/10.1111/jiec.12845 英语 eng WILEY JOURNAL OF INDUSTRIAL ECOLOGY http://ir.qdio.ac.cn/handle/337002/163436 doi:10.1111/jiec.12845 atlantic salmon feed production indoor aquaculture industrial ecology life cycle assessment (LCA) recirculating aquaculture systems Science & Technology - Other Topics Engineering Environmental Sciences & Ecology Green & Sustainable Science & Technology Environmental Environmental Sciences ENVIRONMENTAL-IMPACT PERFORMANCE WATER 期刊论文 2019 ftchinacasciocas https://doi.org/10.1111/jiec.12845 2022-06-27T05:41:24Z Recirculating aquaculture systems (RAS) are an alternative technology to tackle the major environmental challenges associated with conventional cage culture systems. In order to systematically assess the environmental performance of RAS farming, it is important to take the whole life cycle into account so as to avoid ad hoc and suboptimal environmental measures. So far, the application of life cycle assessment (LCA) in aquaculture, especially to indoor RAS, is still in progress. This study reports on an LCA of Atlantic salmon harvested at an indoor RAS farm in northern China. Results showed that 1 tonne live-weight salmon production required 7,509 kWh farm-level electricity and generated 16.7 tonnes of CO2 equivalent (eq), 106 kg of SO2 eq, 2.4 kg of P eq, and 108 kg of N eq (cradle-to-farm gate). In particular, farm-level electricity use and feed product were identified as primary contributors to eight of nine impact categories assessed (54-95% in total), except the potential marine eutrophication (MEU) impact (dominated by the grow-out effluents). Among feed ingredients (on a dry-weight basis), chicken meal (5%) and krill meal (8%) dominated six and three, respectively, of the nine impact categories. Suggested environmental improvement measures for this indoor RAS farm included optimization of stocking density, feeding management, grow-out effluent treatment, substitution of feed ingredients, and selection of electricity generation sources. In a generic context, this study can contribute to a better understanding of the life cycle environmental impacts of land-based salmon RAS operations, as well as science-based communication among stakeholders on more eco-friendly farmed salmon. Report Atlantic salmon Institute of Oceanology, Chinese Academy of Sciences: IOCAS-IR Journal of Industrial Ecology 23 5 1077 1086
institution Open Polar
collection Institute of Oceanology, Chinese Academy of Sciences: IOCAS-IR
op_collection_id ftchinacasciocas
language English
topic atlantic salmon
feed production
indoor aquaculture
industrial ecology
life cycle assessment (LCA)
recirculating aquaculture systems
Science & Technology - Other Topics
Engineering
Environmental Sciences & Ecology
Green & Sustainable Science & Technology
Environmental
Environmental Sciences
ENVIRONMENTAL-IMPACT
PERFORMANCE
WATER
spellingShingle atlantic salmon
feed production
indoor aquaculture
industrial ecology
life cycle assessment (LCA)
recirculating aquaculture systems
Science & Technology - Other Topics
Engineering
Environmental Sciences & Ecology
Green & Sustainable Science & Technology
Environmental
Environmental Sciences
ENVIRONMENTAL-IMPACT
PERFORMANCE
WATER
Song, Xingqiang
Liu, Ying
Pettersen, Johan Berg
Brandao, Miguel
Ma, Xiaona
Roberg, Stian
Frostell, Bjorn
Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China
topic_facet atlantic salmon
feed production
indoor aquaculture
industrial ecology
life cycle assessment (LCA)
recirculating aquaculture systems
Science & Technology - Other Topics
Engineering
Environmental Sciences & Ecology
Green & Sustainable Science & Technology
Environmental
Environmental Sciences
ENVIRONMENTAL-IMPACT
PERFORMANCE
WATER
description Recirculating aquaculture systems (RAS) are an alternative technology to tackle the major environmental challenges associated with conventional cage culture systems. In order to systematically assess the environmental performance of RAS farming, it is important to take the whole life cycle into account so as to avoid ad hoc and suboptimal environmental measures. So far, the application of life cycle assessment (LCA) in aquaculture, especially to indoor RAS, is still in progress. This study reports on an LCA of Atlantic salmon harvested at an indoor RAS farm in northern China. Results showed that 1 tonne live-weight salmon production required 7,509 kWh farm-level electricity and generated 16.7 tonnes of CO2 equivalent (eq), 106 kg of SO2 eq, 2.4 kg of P eq, and 108 kg of N eq (cradle-to-farm gate). In particular, farm-level electricity use and feed product were identified as primary contributors to eight of nine impact categories assessed (54-95% in total), except the potential marine eutrophication (MEU) impact (dominated by the grow-out effluents). Among feed ingredients (on a dry-weight basis), chicken meal (5%) and krill meal (8%) dominated six and three, respectively, of the nine impact categories. Suggested environmental improvement measures for this indoor RAS farm included optimization of stocking density, feeding management, grow-out effluent treatment, substitution of feed ingredients, and selection of electricity generation sources. In a generic context, this study can contribute to a better understanding of the life cycle environmental impacts of land-based salmon RAS operations, as well as science-based communication among stakeholders on more eco-friendly farmed salmon.
format Report
author Song, Xingqiang
Liu, Ying
Pettersen, Johan Berg
Brandao, Miguel
Ma, Xiaona
Roberg, Stian
Frostell, Bjorn
author_facet Song, Xingqiang
Liu, Ying
Pettersen, Johan Berg
Brandao, Miguel
Ma, Xiaona
Roberg, Stian
Frostell, Bjorn
author_sort Song, Xingqiang
title Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China
title_short Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China
title_full Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China
title_fullStr Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China
title_full_unstemmed Life cycle assessment of recirculating aquaculture systems: A case of Atlantic salmon farming in China
title_sort life cycle assessment of recirculating aquaculture systems: a case of atlantic salmon farming in china
publisher WILEY
publishDate 2019
url http://ir.qdio.ac.cn/handle/337002/163436
https://doi.org/10.1111/jiec.12845
genre Atlantic salmon
genre_facet Atlantic salmon
op_relation JOURNAL OF INDUSTRIAL ECOLOGY
http://ir.qdio.ac.cn/handle/337002/163436
doi:10.1111/jiec.12845
op_doi https://doi.org/10.1111/jiec.12845
container_title Journal of Industrial Ecology
container_volume 23
container_issue 5
container_start_page 1077
op_container_end_page 1086
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