Biomass residue to carbon dioxide removal: quantifying the global impact of biochar

Author:

Lefebvre David,Fawzy Samer,Aquije Camila A.,Osman Ahmed I.,Draper Kathleen T.,Trabold Thomas A.ORCID

Abstract

AbstractThe Climate Change Conference of Parties (COP) 21 in December 2015 established Nationally Determined Contributions toward reduction of greenhouse gas emissions. In the years since COP21, it has become increasingly evident that carbon dioxide removal (CDR) technologies must be deployed immediately to stabilize concentration of atmospheric greenhouse gases and avoid major climate change impacts. Biochar is a carbon-rich material formed by high-temperature conversion of biomass under reduced oxygen conditions, and its production is one of few established CDR methods that can be deployed at a scale large enough to counteract effects of climate change within the next decade. Here we provide a generalized framework for quantifying the potential contribution biochar can make toward achieving national carbon emissions reduction goals, assuming use of only sustainably supplied biomass, i.e., residues from existing agricultural, livestock, forestry and wastewater treatment operations. Our results illustrate the significant role biochar can play in world-wide CDR strategies, with carbon dioxide removal potential of 6.23 ± 0.24% of total GHG emissions in the 155 countries covered based on 2020 data over a 100-year timeframe, and more than 10% of national emissions in 28 countries. Concentrated regions of high biochar carbon dioxide removal potential relative to national emissions were identified in South America, northwestern Africa and eastern Europe. Graphical abstract

Publisher

Springer Science and Business Media LLC

Subject

Pollution,Soil Science,Environmental Science (miscellaneous),Biomaterials

Reference65 articles.

1. Adghim M, Abdallah M, Saad S, Shanableh A, Sartaj M, El Mansouri AE (2020) Comparative life cycle assessment of anaerobic co-digestion for dairy waste management in large-scale farms. J Clean Prod 256:120320. https://doi.org/10.1016/j.jclepro.2020.120320

2. AMISY (2020a) High Efficiency Vertical Ring Die Wood Pellet Machine, Wood Pellet Mill. Available at: https://www.wood-pellet-mill.com/product/wood-pellet-mill/vertical-ring-die-wood-pellet-mill.html (Accessed: 15 January 2020a)

3. AMISY (2020b) Wood Hammer Mill, Customized Wood Crushing Machine for Wood Pellet Plant. Available at: https://www.wood-pellet-mill.com/product/wood-crusher/wood-hammer-mill.html (Accessed: 15 January 2020b)

4. Avcıoğlu AO, Dayıoğlu MA, Türker UJRE (2019) Assessment of the energy potential of agricultural biomass residues in Turkey. Renewable Energy 138:610–619. https://doi.org/10.1016/j.renene.2019.01.053

5. Azzi ES, Karltun E, Sundberg C (2021) Assessing the diverse environmental effects of biochar systems: an evaluation framework. J Environ Manag 286:112154. https://doi.org/10.1016/j.jenvman.2021.112154

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