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Linking Material Flow Analysis with Environmental Impact Potential

Author

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  • Carl W. Lam
  • Seong‐Rin Lim
  • Julie M. Schoenung

Abstract

Technology transition can have significant implications on the evolution of environmental impact potential of disposed electronics over time. Considering technology transition, we quantify the temporal behavior of ecological and human health impact potential from select heavy metals in electronic waste (e‐waste). The case study analyzes product substitution effects in two electronic cohorts from the U.S. market: (1) computers (laptops substituting for desktops) and (2) televisions (flat‐panel liquid crystal displays [LCDs] and plasma displays substituting for cathode‐ray tubes [CRTs]). Quantities of end‐of‐life (EoL) units to year 2030 are forecasted by the unique combination of dynamic material flow analysis, logistic trend analysis, and product lifespan calibration methods. Metal content from EoL units are assessed via a pathway and effect model using USETox™ characterization factors to determine the toxicity potential attributed to heavy metal releases into different media (e.g., air, water, and soil) as an indicator of environmental burden. Results show high impact materials such as lead, nickel, and zinc cause changes in human health toxicity potential and copper causes changes in ecological toxicity potential. Effects of dematerialization, such as reduced metal content in laptops over desktops, provide some positive benefits in toxicity potential per product. However, from a market perspective, emerging e‐waste quantities created by increasing per capita penetration rates of electronics and increasing population will offset gains in environmental performance at the product level. The resulting analysis provides guidance on the timing expected for emerging EoL units and an indication of high impact potential materials requiring pollution prevention as product substitution occurs.

Suggested Citation

  • Carl W. Lam & Seong‐Rin Lim & Julie M. Schoenung, 2013. "Linking Material Flow Analysis with Environmental Impact Potential," Journal of Industrial Ecology, Yale University, vol. 17(2), pages 299-309, April.
    • Handle: RePEc:bla:inecol:v:17:y:2013:i:2:p:299-309
    DOI: 10.1111/j.1530-9290.2012.00513.x
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    Cited by:

    1. Dhiya Durani Sofian Azizi & Marlia M. Hanafiah & Kok Sin Woon, 2023. "Material Flow Analysis in WEEE Management for Circular Economy: A Content Review on Applications, Limitations, and Future Outlook," Sustainability, MDPI, vol. 15(4), pages 1-22, February.
    2. Sohani Vihanga Withanage & Komal Habib, 2021. "Life Cycle Assessment and Material Flow Analysis: Two Under-Utilized Tools for Informing E-Waste Management," Sustainability, MDPI, vol. 13(14), pages 1-21, July.
    3. Yuhua Guo & Junmao Qie & Chunxia Zhang & Yuantao Yang, 2021. "Material flow analysis of zinc during the manufacturing process in integrated steel mills in China," Journal of Industrial Ecology, Yale University, vol. 25(4), pages 1009-1020, August.
    4. Kasulaitis, Barbara V. & Babbitt, Callie W. & Kahhat, Ramzy & Williams, Eric & Ryen, Erinn G., 2015. "Evolving materials, attributes, and functionality in consumer electronics: Case study of laptop computers," Resources, Conservation & Recycling, Elsevier, vol. 100(C), pages 1-10.
    5. Minghao Xu & Dingjiang Chen & Yadong Yu & Zengbo Chen & Yupeng Zhang & Bomin Liu & Yike Fu & Bing Zhu, 2021. "Assessing resource consumption at the subnational level: A novel accounting method based on provincial selected material consumption," Journal of Industrial Ecology, Yale University, vol. 25(3), pages 580-592, June.

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