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Biomass residues as twenty-first century bioenergy feedstock—a comparison of eight integrated assessment models

Author

Listed:
  • Steef V. Hanssen

    (Radboud University)

  • Vassilis Daioglou

    (PBL Netherlands Environmental Assessment Agency
    Utrecht University)

  • Zoran J. N. Steinmann

    (Radboud University)

  • Stefan Frank

    (IIASA, International Institute for Applied Systems Analysis)

  • Alexander Popp

    (PIK Potsdam Institute for Climate Impact Research)

  • Thierry Brunelle

    (CIRAD, UMR CIRED)

  • Pekka Lauri

    (IIASA, International Institute for Applied Systems Analysis)

  • Tomoko Hasegawa

    (IIASA, International Institute for Applied Systems Analysis
    Center for Social & Environmental Systems Research, National Institute for Environmental Studies)

  • Mark A. J. Huijbregts

    (Radboud University
    PBL Netherlands Environmental Assessment Agency)

  • Detlef P. Vuuren

    (PBL Netherlands Environmental Assessment Agency
    Utrecht University)

Abstract

In the twenty-first century, modern bioenergy could become one of the largest sources of energy, partially replacing fossil fuels and contributing to climate change mitigation. Agricultural and forestry biomass residues form an inexpensive bioenergy feedstock with low greenhouse gas (GHG) emissions, if harvested sustainably. We analysed quantities of biomass residues supplied for energy and their sensitivities in harmonised bioenergy demand scenarios across eight integrated assessment models (IAMs) and compared them with literature-estimated residue availability. IAM results vary substantially, at both global and regional scales, but suggest that residues could meet 7–50% of bioenergy demand towards 2050, and 2–30% towards 2100, in a scenario with 300 EJ/year of exogenous bioenergy demand towards 2100. When considering mean literature-estimated availability, residues could provide around 55 EJ/year by 2050. Inter-model differences primarily arise from model structure, assumptions, and the representation of agriculture and forestry. Despite these differences, drivers of residues supplied and underlying cost dynamics are largely similar across models. Higher bioenergy demand or biomass prices increase the quantity of residues supplied for energy, though their effects level off as residues become depleted. GHG emission pricing and land protection can increase the costs of using land for lignocellulosic bioenergy crop cultivation, which increases residue use at the expense of lignocellulosic bioenergy crops. In most IAMs and scenarios, supplied residues in 2050 are within literature-estimated residue availability, but outliers and sustainability concerns warrant further exploration. We conclude that residues can cost-competitively play an important role in the twenty-first century bioenergy supply, though uncertainties remain concerning (regional) forestry and agricultural production and resulting residue supply potentials.

Suggested Citation

  • Steef V. Hanssen & Vassilis Daioglou & Zoran J. N. Steinmann & Stefan Frank & Alexander Popp & Thierry Brunelle & Pekka Lauri & Tomoko Hasegawa & Mark A. J. Huijbregts & Detlef P. Vuuren, 2020. "Biomass residues as twenty-first century bioenergy feedstock—a comparison of eight integrated assessment models," Climatic Change, Springer, vol. 163(3), pages 1569-1586, December.
    • Handle: RePEc:spr:climat:v:163:y:2020:i:3:d:10.1007_s10584-019-02539-x
    DOI: 10.1007/s10584-019-02539-x
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    References listed on IDEAS

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    1. Gustavsson, Leif & Haus, Sylvia & Ortiz, Carina A. & Sathre, Roger & Truong, Nguyen Le, 2015. "Climate effects of bioenergy from forest residues in comparison to fossil energy," Applied Energy, Elsevier, vol. 138(C), pages 36-50.
    2. Global Energy Assessment Writing Team,, 2012. "Global Energy Assessment," Cambridge Books, Cambridge University Press, number 9781107005198, Enero.
    3. Nico Bauer & Steven K. Rose & Shinichiro Fujimori & Detlef P. Vuuren & John Weyant & Marshall Wise & Yiyun Cui & Vassilis Daioglou & Matthew J. Gidden & Etsushi Kato & Alban Kitous & Florian Leblanc &, 2020. "Global energy sector emission reductions and bioenergy use: overview of the bioenergy demand phase of the EMF-33 model comparison," Climatic Change, Springer, vol. 163(3), pages 1553-1568, December.
    4. P. M. F. Elshout & R. van Zelm & J. Balkovic & M. Obersteiner & E. Schmid & R. Skalsky & M. van der Velde & M. A. J. Huijbregts, 2015. "Greenhouse-gas payback times for crop-based biofuels," Nature Climate Change, Nature, vol. 5(6), pages 604-610, June.
    5. Jay Gregg & Steven Smith, 2010. "Global and regional potential for bioenergy from agricultural and forestry residue biomass," Mitigation and Adaptation Strategies for Global Change, Springer, vol. 15(3), pages 241-262, March.
    6. Global Energy Assessment Writing Team,, 2012. "Global Energy Assessment," Cambridge Books, Cambridge University Press, number 9780521182935, Enero.
    7. Steven Rose & Elmar Kriegler & Ruben Bibas & Katherine Calvin & Alexander Popp & Detlef Vuuren & John Weyant, 2014. "Bioenergy in energy transformation and climate management," Climatic Change, Springer, vol. 123(3), pages 477-493, April.
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    2. Wu, Yazhen & Deppermann, Andre & Havlík, Petr & Frank, Stefan & Ren, Ming & Zhao, Hao & Ma, Lin & Fang, Chen & Chen, Qi & Dai, Hancheng, 2023. "Global land-use and sustainability implications of enhanced bioenergy import of China," Applied Energy, Elsevier, vol. 336(C).
    3. Hao Li & Pengru Fan & Yukun Wang & Yang Lu & Feng Chen & Haotian Zhang & Bin Zhang & Bo Wang & Zhaohua Wang, 2024. "Integrated assessment models for resource–environment–economy coordinated development," Wiley Interdisciplinary Reviews: Energy and Environment, Wiley Blackwell, vol. 13(3), May.
    4. Porcelli, Roberto & Gibon, Thomas & Marazza, Diego & Righi, Serena & Rugani, Benedetto, 2023. "Prospective environmental impact assessment and simulation applied to an emerging biowaste-based energy technology in Europe," Renewable and Sustainable Energy Reviews, Elsevier, vol. 176(C).
    5. Ibolya Török & Enikő Mátyus & Tihamér-Tibor Sebestyén & Carmen Păunescu & Kinga Xénia Havadi-Nagy, 2024. "Exploring Acceptance of Agro-Biomass as Innovative Solution for Heating in Rural Areas in Romania," Resources, MDPI, vol. 13(11), pages 1-16, October.
    6. M. Millinger & F. Hedenus & E. Zeyen & F. Neumann & L. Reichenberg & G. Berndes, 2025. "Diversity of biomass usage pathways to achieve emissions targets in the European energy system," Nature Energy, Nature, vol. 10(2), pages 226-242, February.

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