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Comparing the Land Requirements, Energy Savings, and Greenhouse Gas Emissions Reduction of Biobased Polymers and Bioenergy

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  • Veronika Dornburg
  • Iris Lewandowski
  • Martin Patel

Abstract

This study compares energy savings and greenhouse gas (GHG) emission reductions of biobased polymers with those of bioenergy on a per unit of agricultural land‐use basis by extending existing life‐cycle assessment (LCA) studies. In view of policy goals to increase the energy supply from biomass and current efforts to produce biobased polymers in bulk, the amount of available land for the production of nonfood crops could become a limitation. Hence, given the prominence of energy and greenhouse issues in current environmental policy, it is desirable to include land demand in the comparison of different biomass options. Over the past few years, numerous LCA studies have been prepared for different types of bio‐based polymers, but only a few of these studies address the aspect of land use. This comparison shows that referring energy savings and GHG emission reduction of biobased polymers to a unit of agricultural land, instead of to a unit of polymer produced, leads to a different ranking of options. If land use is chosen as the basis of comparison, natural fiber composites and thermoplastic starch score better than bioenergy production from energy crops, whereas polylactides score comparably well and polyhydroxyalkaonates score worse. Additionally, including the use of agricultural residues for energy purposes improves the environmental performance of bio‐based polymers significantly. Moreover, it is very likely that higher production efficiencies will be achieved for biobased polymers in the medium term. Biobased polymers thus offer interesting opportunities to reduce the utilization of nonrenewable energy and to contribute to GHG mitigation in view of potentially scarce land resources.

Suggested Citation

  • Veronika Dornburg & Iris Lewandowski & Martin Patel, 2003. "Comparing the Land Requirements, Energy Savings, and Greenhouse Gas Emissions Reduction of Biobased Polymers and Bioenergy," Journal of Industrial Ecology, Yale University, vol. 7(3‐4), pages 93-116, July.
    • Handle: RePEc:bla:inecol:v:7:y:2003:i:3-4:p:93-116
    DOI: 10.1162/108819803323059424
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    Cited by:

    1. Anja Hansen & Jörn Budde & Annette Prochnow, 2016. "Resource Usage Strategies and Trade-Offs between Cropland Demand, Fossil Fuel Consumption, and Greenhouse Gas Emissions—Building Insulation as an Example," Sustainability, MDPI, vol. 8(7), pages 1-24, June.
    2. Broeren, Martijn L.M. & Kuling, Lody & Worrell, Ernst & Shen, Li, 2017. "Environmental impact assessment of six starch plastics focusing on wastewater-derived starch and additives," Resources, Conservation & Recycling, Elsevier, vol. 127(C), pages 246-255.
    3. Sebastian Lubjuhn & Sandra Venghaus, 2024. "Unlocking the potential of the bioeconomy for climate change reduction: The optimal use of lignocellulosic biomass in Germany," Journal of Industrial Ecology, Yale University, vol. 28(1), pages 144-159, February.
    4. Dornburg, V. & Faaij, A. & Patel, M. & Turkenburg, W.C., 2006. "Economics and GHG emission reduction of a PLA bio-refinery system—Combining bottom-up analysis with price elasticity effects," Resources, Conservation & Recycling, Elsevier, vol. 46(4), pages 377-409.
    5. Emilia Jankowska & Miranda R. Gorman & Chad J. Frischmann, 2022. "Transforming the Plastic Production System Presents Opportunities to Tackle the Climate Crisis," Sustainability, MDPI, vol. 14(11), pages 1-18, May.

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