Sarah A. Kruse scite author profile

We present a global-scale life cycle assessment of a major food commodity, farmed salmon. Specifically, we report the cumulative energy use, biotic resource use, and greenhouse gas, acidifying, and eutrophying emissions associated with producing farmed salmon in Norway, the UK, British Columbia (Canada), and Chile, as well as a production-weighted global average. We found marked differences in the nature and quantity of material/energy resource use and associated emissions per unit production across regions. This suggests significant scope for improved environmental performance in the industry as a whole. We identify key leverage points for improving performance, most notably the critical importance of least-environmental cost feed sourcing patterns and continued improvements in feed conversion efficiency. Overall, impacts were lowest for Norwegian production in most impact categories, and highest for UK farmed salmon. Our results are of direct relevance to industry, policy makers, eco-labeling programs, and consumers seeking to further sustainability objectives in salmon aquaculture.

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A comparison of approaches used for economic analysis in marine protected area network planning in California

White

Scholz²,

Rassweiler

et al. 2013

Ocean & Coastal Management

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Impact categories for life cycle assessment research of seafood production systems: Review and prospectus

Pelletier

Ayer

Tyedmers

et al. 2006

Int J Life Cycle Assessment

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Socioeconomic indicators as a complement to life cycle assessment—an application to salmon production systems

Kruse

Flysjö

Kasperczyk³

et al. 2008

Int J Life Cycle Assess

103

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Background, aim, and scope There is a growing recognition on the part of industry, policymakers, and consumers that sustainable industry practices are needed to maintain environmental and social well being. Life cycle assessment (LCA) is an internationally standardized analytical framework that has traditionally focused on evaluation of the environmental impacts of processes or products using a cradle-to-grave approach. Yet, sustainability, defined generally, requires that assessments consider not only environmental but also social and economic impacts-the other two pillars of sustainability. Even though the LCA methodology has the potential to include both social and economic indicators, and SETAC guidelines recommend the inclusion of such impact categories in all detailed LCAs, no established set of metrics exists to describe the relationship between socioeconomic indicators (SEIs) and a specific product or process; nor is there a common understanding on how such metrics might be developed. This article presents the methods for and development of a suite of socioeconomic indicators that complement the LCA methodology and provides a comprehensive approach for assessing the cradle-to-grave sustainability of a product or process.Methods A combined top-down and bottom-up approach serves as the basis for development of the set of socioeconomic indicators presented here. Generally recognized societal values, industry specific issues, and financial constraints associated with collection of data necessary for measurement of the indicators are all factors considered in this approach. In our categorization, socioeconomic indicators fall into two types: additive indicators and descriptive indicators. Results Indicators are categorized based on fundamental methodological differences and then used to describe the socioeconomic impacts associated with salmon production. Additive indicators (e.g., production costs and value added) and descriptive indicators (e.g., fair wage and contribution to personal income) are both discussed. Discussion There is a need to further develop and refine methods to assess the results of socioeconomic indicators using a life cycle perspective. It would be most interesting to conduct additional case studies that focus on such methodological development, particularly trade-offs between stakeholder groups and pillars of sustainability. Additional areas of discussion are (1) the need for data to populate socioeconomic indicators and (2) defining system boundaries for socioeconomic indicators. Conclusions This article presents a set of socioeconomic indicators designed to serve as a complement for the LCA framework, thus, increasing the framework's effectiveness as a measure of the overall sustainability of a product or process. Development of socioeconomic indicators as a complement to LCA is still in its early stages, however, and further research is required.

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Sarah A. Kruse

Not All Salmon Are Created Equal: Life Cycle Assessment (LCA) of Global Salmon Farming Systems

A comparison of approaches used for economic analysis in marine protected area network planning in California

Impact categories for life cycle assessment research of seafood production systems: Review and prospectus

Socioeconomic indicators as a complement to life cycle assessment—an application to salmon production systems

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