Bioenergy production and sustainable development: science base for policymaking remains limited

Carmenza Robledo-Abad¹, Hans-Jörg Althaus², Göran Berndes³, Simon Bolwig⁴, Esteve Corbera⁵, Felix Creutzig⁶, John Garcia-Ulloa⁷, Anna Geddes⁸, Jay S Gregg⁴, Helmut Haberl⁹, Susanne Hanger¹⁰, Richard J Harper¹¹, Carol Hunsberger¹², Rasmus K Larsen¹³, Christian Lauk⁹, Stefan Leitner⁹, Johan Lilliestam⁸, Hermann Lotze-Campen¹⁴, Bart Muys¹⁵, Maria Nordborg³, Maria Ölund¹⁶, Boris Orlowsky¹⁷, Alexander Popp¹⁸, Joana Portugal-Pereira¹⁹, Jürgen Reinhard²⁰, Lena Scheiffle¹⁸, Pete Smith²¹

Affiliations

¹ Department of Environmental Systems Science USYS Td Lab ETH Zürich Universitätstrasse 228092 Zurich Switzerland; Helvetas Swiss Intercooperation Maulbeerstr. 10CH-3001 Bern Switzerland.
² Foundation for Global Sustainability (ffgs) Reitergasse 118004 Zürich Switzerland; Lifecycle Consulting Althaus Bruechstr. 1328706 Meilen Switzerland.
³ Department of Energy and Environment Chalmers University of Technology SE 41296 Gothenburg Sweden.
⁴ DTU Management Engineering Technical University of Denmark 4000 Roskilde Denmark.
⁵ Institute of Environmental Science and Technology, and Department of Economics & Economic History Universitat Autònoma de Barcelona 08193 Barcelona Spain.
⁶ Mercator Research Institute on Global Commons and Climate Change & Technical University Berlin 10829 Berlin Germany.
⁷ Institute of Terrestrial Ecosystems ETH Zürich Universitätstrasse 22, 8092 Zurich Switzerland.
⁸ Institute for Environmental Decisions ETH Zürich Climate Policy Group Universitätstrasse 22 8092 Zurich Switzerland.
⁹ Institute of Social Ecology Vienna (SEC) Alpen-Adria Universitaet (AAU) Schottenfeldgasse 29 1070 Vienna Austria.
¹⁰ Institute for Environmental Decisions ETH Zürich Climate Policy Group Universitätstrasse 228092 Zurich Switzerland; International Institute for Applied Systems Analysis Schlossplatz 1 Laxenburg Austria.
¹¹ School of Veterinary and Life Sciences Murdoch University South Street Murdoch WA 6150 Australia.
¹² Department of Geography University of Western Ontario London ON N6A 5C2 Canada.
¹³ Stockholm Environment Institute (SEI) Linnégatan 87D 115 23 Stockholm Postbox 24218 104 51 Stockholm Sweden.
¹⁴ Potsdam Institute for Climate Impact Research (PIK) PO Box 60120314412 Potsdam Germany; Humboldt-University zu Berlin Unter den Linden 610099 Berlin Germany.
¹⁵ Division of Forest, Nature and Landscape University of Leuven (KU Leuven) Celestijnenlaan 200E box 2411 BE- 3001 Leuven Belgium.
¹⁶ Centre for Environment and Sustainability - GMV University of Gothenburg Aschebergsgatan 44 Göteborg Sweden.
¹⁷ Climate-Babel.
¹⁸ Potsdam Institute for Climate Impact Research (PIK) PO Box 601203 14412 Potsdam Germany.
¹⁹ Energy Planning Program COPPE, Federal University of Rio de Janeiro Centro de Tecnologia Sala C-211, C.P. 68565, Cidade Universitária Ilha do Fundão 21941-972 Rio de Janeiro RJ Brazil.
²⁰ Informatics and Sustainability Research Group Swiss Federal Institute for Material Testing and Research Empa, Ueberlandstrasse 129 8600 Duebendorf Switzerland.
²¹ Institute of Biological & Environmental Sciences ClimateXChange and Scottish Food Security Alliance-Crops University of Aberdeen 23 St Machar Drive Aberdeen AB24 3UU UK.

PMID: 28331552
PMCID: PMC5340281
DOI: 10.1111/gcbb.12338

Review

Bioenergy production and sustainable development: science base for policymaking remains limited

Carmenza Robledo-Abad et al. Glob Change Biol Bioenergy. 2017 Mar.

. 2017 Mar;9(3):541-556.

doi: 10.1111/gcbb.12338. Epub 2016 Mar 23.

Authors

Affiliations

¹ Department of Environmental Systems Science USYS Td Lab ETH Zürich Universitätstrasse 228092 Zurich Switzerland; Helvetas Swiss Intercooperation Maulbeerstr. 10CH-3001 Bern Switzerland.
² Foundation for Global Sustainability (ffgs) Reitergasse 118004 Zürich Switzerland; Lifecycle Consulting Althaus Bruechstr. 1328706 Meilen Switzerland.
³ Department of Energy and Environment Chalmers University of Technology SE 41296 Gothenburg Sweden.
⁴ DTU Management Engineering Technical University of Denmark 4000 Roskilde Denmark.
⁵ Institute of Environmental Science and Technology, and Department of Economics & Economic History Universitat Autònoma de Barcelona 08193 Barcelona Spain.
⁶ Mercator Research Institute on Global Commons and Climate Change & Technical University Berlin 10829 Berlin Germany.
⁷ Institute of Terrestrial Ecosystems ETH Zürich Universitätstrasse 22, 8092 Zurich Switzerland.
⁸ Institute for Environmental Decisions ETH Zürich Climate Policy Group Universitätstrasse 22 8092 Zurich Switzerland.
⁹ Institute of Social Ecology Vienna (SEC) Alpen-Adria Universitaet (AAU) Schottenfeldgasse 29 1070 Vienna Austria.
¹⁰ Institute for Environmental Decisions ETH Zürich Climate Policy Group Universitätstrasse 228092 Zurich Switzerland; International Institute for Applied Systems Analysis Schlossplatz 1 Laxenburg Austria.
¹¹ School of Veterinary and Life Sciences Murdoch University South Street Murdoch WA 6150 Australia.
¹² Department of Geography University of Western Ontario London ON N6A 5C2 Canada.
¹³ Stockholm Environment Institute (SEI) Linnégatan 87D 115 23 Stockholm Postbox 24218 104 51 Stockholm Sweden.
¹⁴ Potsdam Institute for Climate Impact Research (PIK) PO Box 60120314412 Potsdam Germany; Humboldt-University zu Berlin Unter den Linden 610099 Berlin Germany.
¹⁵ Division of Forest, Nature and Landscape University of Leuven (KU Leuven) Celestijnenlaan 200E box 2411 BE- 3001 Leuven Belgium.
¹⁶ Centre for Environment and Sustainability - GMV University of Gothenburg Aschebergsgatan 44 Göteborg Sweden.
¹⁷ Climate-Babel.
¹⁸ Potsdam Institute for Climate Impact Research (PIK) PO Box 601203 14412 Potsdam Germany.
¹⁹ Energy Planning Program COPPE, Federal University of Rio de Janeiro Centro de Tecnologia Sala C-211, C.P. 68565, Cidade Universitária Ilha do Fundão 21941-972 Rio de Janeiro RJ Brazil.
²⁰ Informatics and Sustainability Research Group Swiss Federal Institute for Material Testing and Research Empa, Ueberlandstrasse 129 8600 Duebendorf Switzerland.
²¹ Institute of Biological & Environmental Sciences ClimateXChange and Scottish Food Security Alliance-Crops University of Aberdeen 23 St Machar Drive Aberdeen AB24 3UU UK.

PMID: 28331552
PMCID: PMC5340281
DOI: 10.1111/gcbb.12338

Abstract

The possibility of using bioenergy as a climate change mitigation measure has sparked a discussion of whether and how bioenergy production contributes to sustainable development. We undertook a systematic review of the scientific literature to illuminate this relationship and found a limited scientific basis for policymaking. Our results indicate that knowledge on the sustainable development impacts of bioenergy production is concentrated in a few well-studied countries, focuses on environmental and economic impacts, and mostly relates to dedicated agricultural biomass plantations. The scope and methodological approaches in studies differ widely and only a small share of the studies sufficiently reports on context and/or baseline conditions, which makes it difficult to get a general understanding of the attribution of impacts. Nevertheless, we identified regional patterns of positive or negative impacts for all categories - environmental, economic, institutional, social and technological. In general, economic and technological impacts were more frequently reported as positive, while social and environmental impacts were more frequently reported as negative (with the exception of impacts on direct substitution of GHG emission from fossil fuel). More focused and transparent research is needed to validate these patterns and develop a strong science underpinning for establishing policies and governance agreements that prevent/mitigate negative and promote positive impacts from bioenergy production.

Keywords: agriculture; bioenergy; food security; forestry; mitigation; sustainable development.

PubMed Disclaimer

Figures

**Figure 1**
Regional distribution of the analysed impacts, reported as fraction of impacts within each category of all impacts analysed in each region. Percentage numbers after the region's name indicate the share of this region in the total of impacts considered and determine the size of the circle. Percentage numbers in the pies indicate the share of impacts each category contributes to the total number of impacts reported in the respective region. For all regions, the most reported social impact is food security; all other social impacts follow far behind. The outline map is from http://www.zonu.com/images/0X0/2009-11-05-10853/World-outline-map.png.

**Figure 2**
Impacts tree regarding food security. The blue arrows show the geographical distribution of the impacts on food security per regions as considered in the studies. In this case, there were no studies considering food security in Oceania. The first line indicates the number of positive (marked in green), negative (marked in red) or neutral impacts (marked in black). When the article did not specify the qualification of the impact, we considered it as nonavailable (n/a, marked in grey). From the second line downwards, we present how these impacts were identified, either using measurements, models or a combination (mixed). When the method was not clear in the article, we defined it as nonavailable (n/a). Impact trees for all other impacts considered in this systematic review are included in the supplementary information.

**Figure 3**
Geographical distribution of studies differentiating between studies considering or not considering context conditions. Solid colours indicate the number of studies with fully or partially matching context conditions. Transparent colours indicate the number of studies where context conditions were either not mentioned or do not correspond to the impact categories.

**Figure 4**
Impacts of bioenergy on food security related to the context conditions considered in this review. Y axis refers to number of articles, and X axis refers to context conditions following the numbering below. Dark grey shows the impacts attributed to dedicated agricultural crops, and hell grey indicates impacts attributed to any other biomass resource. Numbers in axis x numbering: (1) general conditions described. Institutional conditions: (2) the majority of households have access to energy; (3) land tenure clarified; (4) landscape management plan exists; (5) landscape policies exist and are enforced; (6) participation mechanisms are in place; (7) mechanisms for sectorial coordination are in place; (8) existing and enforced labour rights legislation; social conditions: (9) existing deficit in food access and/or supply; (10) existing social conflicts; (11) population growth is expected; (12) awareness about indigenous knowledge; (13) existing social networks/stakeholder organizations; (14) high average human capacity and skills; (15) low average human capacity skills; (16) equity mechanisms are in place; (17) social inequity reported as existing before bioenergy production; natural conditions: (18) land is available for people living in the area; (19) water for agriculture/forestry is available for people living in the area; (20) drinking water is available to people living in the area; (21) land (use) competition previous any intervention is reported in the article; (22) air quality is reported as good; (23) high biodiversity index. Economic conditions: (24) availability of capital; (25) existing crediting mechanisms; (26) sharing mechanisms of economic benefits in place; conditions related to technology and infrastructure: (27) traditional technologies; (28) modern (industrial) technologies; (29) combination of modern and industrial technologies; (30) technology is available to major local stakeholders; (31) mechanisms for technology development and/or transfer given.

See this image and copyright information in PMC

Cited by

Robust paths to net greenhouse gas mitigation and negative emissions via advanced biofuels.
Field JL, Richard TL, Smithwick EAH, Cai H, Laser MS, LeBauer DS, Long SP, Paustian K, Qin Z, Sheehan JJ, Smith P, Wang MQ, Lynd LR. Field JL, et al. Proc Natl Acad Sci U S A. 2020 Sep 8;117(36):21968-21977. doi: 10.1073/pnas.1920877117. Epub 2020 Aug 24. Proc Natl Acad Sci U S A. 2020. PMID: 32839342 Free PMC article.
Assessment of UV radiation emitted by linear fluorescent lamps in Iran.
Dehghani MH, Bazargani A, Mirdoraghi M. Dehghani MH, et al. MethodsX. 2019 Feb 28;6:477-481. doi: 10.1016/j.mex.2019.02.031. eCollection 2019. MethodsX. 2019. PMID: 30923685 Free PMC article.
Forest landscape restoration: state of play.
Stanturf JA, Mansourian S. Stanturf JA, et al. R Soc Open Sci. 2020 Dec 23;7(12):201218. doi: 10.1098/rsos.201218. eCollection 2020 Dec. R Soc Open Sci. 2020. PMID: 33489272 Free PMC article.
Hot stuff: Research and policy principles for heat decarbonisation through smart electrification.
Lowes R, Rosenow J, Qadrdan M, Wu J. Lowes R, et al. Energy Res Soc Sci. 2020 Dec;70:101735. doi: 10.1016/j.erss.2020.101735. Epub 2020 Sep 6. Energy Res Soc Sci. 2020. PMID: 32923371 Free PMC article.
Understanding the sustainability debate on forest biomass for energy in Europe: A discourse analysis.
Mather-Gratton ZJ, Larsen S, Bentsen NS. Mather-Gratton ZJ, et al. PLoS One. 2021 Feb 17;16(2):e0246873. doi: 10.1371/journal.pone.0246873. eCollection 2021. PLoS One. 2021. PMID: 33596217 Free PMC article.

References

1. Ackerman F, DeCanio SJ, Howarth RB, Sheeran K (2009) Limitations of integrated assessment models of climate change. Climatic Change, 95, 297–315.
1. Allwood JM, Bosetti V, Dubash NK, Gómez‐Echeverri L, von Stechow C (2014) Glossary In: Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change (eds Edenhofer O, Pichs‐Madruga R, Sokona Y, Farahani E, Kadner S, Seyboth K, Adler A, Baum I, Brunner S, Eickemeier P, Kriemann B, Savolainen J, Schlömer S, von Stechow C, Zwickel T, Minx JC.), pp. 1249–1279. Cambridge University Press, Cambridge, UK and New York, NY, USA.
1. Bartolucci AA, Hillegass WB (2010) Overview, strengths, and limitations of systematic reviews and meta‐analyses In: Evidence‐Based Practice: Toward Optimizing Clinical Outcomes (ed. Chiappelli F.), pp. 17–33. Springer, Berlin Heidelberg; (ISBN: 978‐3‐642‐05024‐4). Available at: http://link.springer.com/chapter/10.1007/978-3-642-05025-1_2 (accessed 05 March 2013). - DOI
1. Beringer T, Lucht W, Schaphoff S (2011) Bioenergy production potential of global biomass plantations under environmental and agricultural constraints. Global Change Biology Bioenergy, 3, 299–312.
1. Brandao M, Levasseur A, Kirschbaum MUF et al (2013) Key issues and options in accounting for carbon sequestration and temporary storage in life cycle assessment and carbon footprinting. International Journal of Life Cycle Assessment, 18, 230–240.

Publication types

Actions

LinkOut - more resources

Full Text Sources
Other Literature Sources
- scite Smart Citations

Save citation to file

Email citation

Add to Collections

Add to My Bibliography

Your saved search

Create a file for external citation management software

Your RSS Feed

Bioenergy production and sustainable development: science base for policymaking remains limited

Affiliations

Bioenergy production and sustainable development: science base for policymaking remains limited

Authors

Affiliations

Abstract

Figures

Similar articles

Cited by

References

Publication types

LinkOut - more resources

Full Text Sources

Other Literature Sources