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References (20)
-
Jürgen Reinhard, R. Zah (2009)
Global environmental consequences of increased biodiesel consumption in Switzerland: consequential life cycle assessmentJournal of Cleaner Production, 17
-
P. Fearnside (2002)
Why a 100-Year Time Horizon should be used for GlobalWarming Mitigation CalculationsMitigation and Adaptation Strategies for Global Change, 7
-
A Abiola (2010)
1309Comput Aided Chem Eng, 28
-
B. Sandén, M. Karlström (2007)
Positive and negative feedback in consequential life-cycle assessmentJournal of Cleaner Production, 15
-
Arinola Abiola, E. Fraga, P. Lettieri (2010)
Multi-Objective Design for the Consequential Life Cycle Assessment of Corn Ethanol ProductionComputer-aided chemical engineering, 28
-
M. Thomassen, R. Dalgaard, R. Heijungs, I. Boer (2008)
Attributional and consequential LCA of milk productionThe International Journal of Life Cycle Assessment, 13
-
Jürgen Reinhard, R. Zah (2011)
Consequential life cycle assessment of the environmental impacts of an increased rapemethylester (RME) production in SwitzerlandBiomass & Bioenergy, 35
-
Göran Finnveden, M. Hauschild, T. Ekvall, J. Guinée, R. Heijungs, S. Hellweg, A. Koehler, D. Pennington, S. Suh (2009)
Recent developments in Life Cycle Assessment.Journal of environmental management, 91 1
-
K. Shine, J. Fuglestvedt, K. Hailemariam, N. Stuber (2005)
Alternatives to the Global Warming Potential for Comparing Climate Impacts of Emissions of Greenhouse GasesClimatic Change, 68
-
J. Earles, A. Halog (2011)
Consequential life cycle assessment: a reviewThe International Journal of Life Cycle Assessment, 16
-
Jannick Schmidt (2010)
Comparative life cycle assessment of rapeseed oil and palm oilThe International Journal of Life Cycle Assessment, 15
-
K. Shine (2009)
The global warming potential—the need for an interdisciplinary retrialClimatic Change, 96
-
T. Ekvall, B. Weidema (2004)
System boundaries and input data in consequential life cycle inventory analysisThe International Journal of Life Cycle Assessment, 9
-
H. Lund, B. Mathiesen, P. Christensen, J. Schmidt (2010)
Energy system analysis of marginal electricity supply in consequential LCAThe International Journal of Life Cycle Assessment, 15
-
Katsumasa Tanaka, G. Peters, J. Fuglestvedt (2010)
Policy Update: Multicomponent climate policy: why do emission metrics matter?Carbon Management, 1
-
B. Weidema, Jannick Schmidt (2010)
Avoiding Allocation in Life Cycle Assessment RevisitedJournal of Industrial Ecology, 14
-
R. Dalgaard, J. Schmidt, N. Halberg, P. Christensen, M. Thrane, W. Pengue (2008)
LCA of soybean mealThe International Journal of Life Cycle Assessment, 13
-
M. Brandão, R. Clift, A. Cowie, S. Greenhalgh (2014)
The Use of Life Cycle Assessment in the Support of Robust (Climate) Policy Making: Comment on “Using Attributional Life Cycle Assessment to Estimate Climate‐Change Mitigation …”Journal of Industrial Ecology, 18
-
B. Weidema (2009)
Avoiding or Ignoring UncertaintyJournal of Industrial Ecology, 13
-
S. Suh, B. Weidema, J. Schmidt, R. Heijungs (2010)
Generalized Make and Use Framework for Allocation in Life Cycle AssessmentJournal of Industrial Ecology, 14
- Publisher
- Springer Netherlands
- Copyright
- © The Author(s) 2021
- ISBN
- 978-94-024-2097-5
- Pages
- 109 –125
- DOI
- 10.1007/978-94-024-2099-9_4
- Publisher site
- See Chapter on Publisher Site
Abstract
[This study shows that an integrated and holistic sustainability assessment is both possible and relevant. Given the multitude of objectives related to land-use policy, it is relevant that an integrated environmental and economic assessment is performed to identify the most sustainable land use strategies. This has been proposed in an approach where the different criteria are not weighted and traded. An application of this framework to land-use strategies in the UK shows that the current support for biofuel production is misguided by unclear objectives. While it may make sense in meeting the objectives of security of both fuel supply and farmers income, this research study indicates that for the mitigation of both climate change and ecosystem services and biodiversity loss, biofuel strategies are highly inefficient and, therefore, largely redundant. This research links very clearly with multi-objective linear programming and optimisation and with multiple criteria decision analysis, at large. Further research could include linking the proposed life cycle, bio-economic, economy-wide and dynamic model with a multi-objective optimisation model whereby all the relevant targets and variables are captured. An example of this could include the optimisation of land use in Europe, with regards to environmental, economic and social objectives. It could include several environmental constraints, as well as targets that can be explored in combination or separately through scenarios. Additional research needs include, particularly, the validation and calibration of characterisation models used in Life Cycle Impact Assessment for land use impacts on climate and on ecosystem services and biodiversity.]
Published: Apr 16, 2021
Keywords: Land-use competition; Integrated assessment; Multi-objective optimisation; Biofuels; Bioeconomy