Circularity indicators and added value to traditional LCA impact categories: example of pig production

Purpose The purpose of using circularity indicators is to show the effect of changes from linear to more circular systems. This paper contributes to highlighting the importance of methodological aspects of circularity indicators in the agricultural sector when using a life cycle thinking approach. S...

Full description

Saved in:
Bibliographic Details
Published in:The international journal of life cycle assessment 2024-08, Vol.29 (8), p.1380-1392
Main Authors: Møller, Hanne, Lyng, Kari-Anne, Röös, Elin, Samsonstuen, Stine, Olsen, Hanne Fjerdingby
Format: Article
Language:English
Subjects:
Agricultural industry
Agricultural practices
Agricultural wastes
Anaerobic digestion
Animal and Dairy Science
Bread
Carbon
Carbon sequestration
Categories
Circularity
Cover crops
Crop production
Earth and Environmental Science
Economics
Emissions
Environment
Environmental Chemistry
Environmental Economics
Environmental Engineering/Biotechnology
Eutrophication
Fertilization
Food processing industry wastes
Food production
Food waste
Husdjursvetenskap
Indicators
Land use
Lca for Agriculture
Life cycle analysis
Life cycle assessment
Livestock
Nationalekonomi
Nitrogen
Organic carbon
Organic soils
Renewable energy
Renewable resources
Swine
Swine production
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Purpose The purpose of using circularity indicators is to show the effect of changes from linear to more circular systems. This paper contributes to highlighting the importance of methodological aspects of circularity indicators in the agricultural sector when using a life cycle thinking approach. Selected circularity indicators have been explored and compared with LCA impact categories by using them to evaluate the circularity of a livestock system. Methods Circularity indicators were tested on a theoretical pig production system where several circularity strategies and associated mitigation actions were applied. The strategies and mitigation actions were as follows: anaerobic digestion of manure (closing resource loops), anaerobic digestion of bread waste (closing resource loops), precision fertilization (narrowing resource loops), use of cover crops in feed production (regenerating resource flows), and use of bread waste as feed (slowing resource loops). The functional unit was 1 kg pork as carcass weight, and the treatment of 1.1 kg bread waste for all impact categories and indicators. For each mitigation action, relevant circularity indicators were tested. Based on this, the functionality and suitability of these indicators were discussed. Results and discussion Four of the circularity indicators were based on nitrogen (N) or phosphorus (P) substances: N recycling index , partial N balance , consumption of fossil-P fertilizers , and emissions to water bodies (P) . Even if the indicators do not capture the impact of emissions of N and P as the eutrophication impact categories, they provide a useful indication of the circularity of a system. The other three circularity indicators tested were as follows: renewable energy production , soil organic carbon , and land use ratio . The renewable energy production indicator is easy to understand and communicate and provides unique information. Soil organic carbon presents a potential for soil carbon sequestration. Land use ratio is based on the same data as land occupation but provides an assessment of whether feed production competes for the suitable area for food production by including production of human-digestible protein. Conclusions Circularity indicators provide valuable information about the circularity of an agricultural product system. The circularity indicators and LCA impact categories can be used either separately or together, or to complement each other. The choice of indicators depends on the qu
ISSN:0948-3349
1614-7502
1614-7502
DOI:10.1007/s11367-023-02150-4