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Producing energy while sequestering carbon? The relationship between biochar and agricultural productivity

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  • Kauffman, Nathan
  • Dumortier, Jerome
  • Hayes, Dermot J.
  • Brown, Robert C.
  • Laird, David

Abstract

A partial solution to problems associated with anthropogenic greenhouse gas (GHG) emissions could be the development and deployment of carbon-negative technologies, i.e., producing energy while reducing atmospheric carbon dioxide levels. Biofuels have been considered a possibility but have faced limitations due to competition with food production and GHG emissions through indirect land-use change (ILUC). In this article, we show how emissions from ILUC can potentially be reduced by producing food and bioenergy from biochar amended soils. The possibility of yield improvements from biochar would reduce the land requirement for crop production and thus, lead to a reduction in emissions from ILUC. In our application, biochar and bio-oil are produced via fast pyrolysis of corn stover. Bio-oil is subsequently upgraded into a fuel suitable for use in internal combustion engines. Applying the U.S. regulatory method used to determine biofuel life cycle emissions, our results show that a biochar-induced yield improvement in the U.S. Midwest ranging from 1% to 8% above trend can lead to an ILUC credit between 1.65 and 14.79 t CO2-equivalent ha−1 year−1 when future emissions are assessed over the next 30 years. The model is generalizable to other feedstocks and locations and illustrates the relationship between biochar and crop production.

Suggested Citation

  • Kauffman, Nathan & Dumortier, Jerome & Hayes, Dermot J. & Brown, Robert C. & Laird, David, 2014. "Producing energy while sequestering carbon? The relationship between biochar and agricultural productivity," ISU General Staff Papers 201404010700001488, Iowa State University, Department of Economics.
    • Handle: RePEc:isu:genstf:201404010700001488
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    Cited by:

    1. Sara Rajabi Hamedani & Tom Kuppens & Robert Malina & Enrico Bocci & Andrea Colantoni & Mauro Villarini, 2019. "Life Cycle Assessment and Environmental Valuation of Biochar Production: Two Case Studies in Belgium," Energies, MDPI, vol. 12(11), pages 1-21, June.
    2. Monlau, F. & Francavilla, M. & Sambusiti, C. & Antoniou, N. & Solhy, A. & Libutti, A. & Zabaniotou, A. & Barakat, A. & Monteleone, M., 2016. "Toward a functional integration of anaerobic digestion and pyrolysis for a sustainable resource management. Comparison between solid-digestate and its derived pyrochar as soil amendment," Applied Energy, Elsevier, vol. 169(C), pages 652-662.
    3. McKenzie Thomas & Kimberly L. Jensen & Dayton M. Lambert & Burton C. English & Christopher D. Clark & Forbes R. Walker, 2021. "Consumer Preferences and Willingness to Pay for Potting Mix with Biochar," Energies, MDPI, vol. 14(12), pages 1-16, June.
    4. Feng, Qunjie & Lin, Yunqin, 2017. "Integrated processes of anaerobic digestion and pyrolysis for higher bioenergy recovery from lignocellulosic biomass: A brief review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 77(C), pages 1272-1287.
    5. Ningning Ma & Lili Zhang & Yulan Zhang & Lijie Yang & Chunxiao Yu & Guanghua Yin & Timothy A Doane & Zhijie Wu & Ping Zhu & Xingzhu Ma, 2016. "Biochar Improves Soil Aggregate Stability and Water Availability in a Mollisol after Three Years of Field Application," PLOS ONE, Public Library of Science, vol. 11(5), pages 1-10, May.
    6. Salgado, Mario A. Heredia & Tarelho, Luís A.C. & Matos, Arlindo & Robaina, M. & Narváez, Ricardo & Peralta, Miguel E., 2018. "Thermoeconomic analysis of integrated production of biochar and process heat from quinoa and lupin residual biomass," Energy Policy, Elsevier, vol. 114(C), pages 332-341.
    7. Yang, Qiushuang & Mašek, Ondřej & Zhao, Ling & Nan, Hongyan & Yu, Shitong & Yin, Jianxiang & Li, Zhaopeng & Cao, Xinde, 2021. "Country-level potential of carbon sequestration and environmental benefits by utilizing crop residues for biochar implementation," Applied Energy, Elsevier, vol. 282(PB).

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