End-of-life LCA allocation methods: Open loop recycling impacts on robustness of material selection decisions

Materials selection decisions exhibit great influence on the environmental performance of firms through their impact on processing technology, product form, and supply chain configuration. Consequently, materials dictate a product's environmental profile via the burden associated with extractio...

Full description

Saved in:
Bibliographic Details
Main Authors: Nicholson, A.L., Olivetti, E.A., Gregory, J.R., Field, F.R., Kirchain, R.E.
Format: Conference Proceeding
Language:English
Subjects:
Conducting materials
end-of-life
Filters
Humans
ISO standards
life cycle assessment
Materials science and technology
materials selection
Power engineering and energy
Recycling
Robustness
Supply chains
Systems engineering and theory
Citations: Items that cite this one
Online Access:Request full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Materials selection decisions exhibit great influence on the environmental performance of firms through their impact on processing technology, product form, and supply chain configuration. Consequently, materials dictate a product's environmental profile via the burden associated with extraction and refining, transformation from material to product, product performance characteristics during use, and potential recovery at end-of-life (EOL). While lifecycle assessment (LCA) methods provide quantitative input to a product designer's materials selection decision, LCA implementations are evolving and disparate. This work explores several analytical variations of LCA related to the allocation of recycling impacts at product EOL and the implications of these variants across a range of contexts. Stylized analyses across a range of materials are presented, focusing on materials with varying primary and secondary materials production burdens. This work illustrates that a) the application of distinct EOL allocation methods give different values of cumulative environmental impact for the same material, b) these impacts change at differing rates between the various methods, and c) these disparities can result in different rank ordering of materials preference. Characterizing this behavior over a range of parameters illustrates the potential trends in allocation method bias for or against particular materials classes.
ISSN:1095-2020
2378-7260
DOI:10.1109/ISSST.2009.5156769