1st ICAI 2020

International Conference on Automotive Industry 2020

Mladá Boleslav, Czech Republic

References [1] Bauer, C., Hofer, J., Althaus, H.J., Del Duce, A. and Simons, A. (2015). The envi- ronmental performance of current and future passenger vehicles. Life cycle assessment based on a novel scenario analysis framework, Applied Energy , vol. 157, pp. 871-883. [2] Burchart-Korol, D. (2018). The possibilities and challenges for application of life cycle assessment for support sustainable transport. In Carpathian Logistic Congress, CLC 2018. Prague. [3] Burchart-Korol D., Jursova S., Folęga P. and Pustejovska P. (2020). Life cycle impact assessment of electric vehicle battery charging in European Union countries, Journal of Cleaner Production , vol. 257, doi.org/10.1016/j.jclepro.2020.120476 [4] Burchart-Korol, D., Korol, J. and Fugiel A. (2014). Development of eco-efficiency evaluation with multicriteria analysis for steel production. In 23rd International Conference on Metallurgy and Materials, METAL 2014. Brno. [5] Domingues A. R., Marques P., Garcia R., Freire F. and Dias L.C. (2015). Applying multicriteria decision analysis to the lifecycle assessment of vehicles, Journal of Cleaner Production , vol. 107, pp. 749-759. [6] Ekener E., Hansson J., Larsson A. and Peck P. (2018). Developing Life Cycle Sustainability Assessment methodology by applying values-based sustainability weighting – Tested on biomass based and fossil transportation fuels , Journal of Cleaner Production , vol. 181, pp. 337-351. [7] Finkbeiner, M., Schau, E.M., Lehmann, A. and Traverso, M. (2010). Towards Life Cycle Sustainability Assessment. Sustainability , vol. 2, pp. 3309-3322. [8] Gemechu, E.D., Sonnemann, G. and Young, S.B. (2017). Geopolitical-related supply risk assessment as a complement to environmental impact assessment: the case of electric vehicles., The International Journal of Life Cycle Assessment , vol. 22, pp. 31-39. [9] Girubha R.J. andVinodh S. (2012). Application of fuzzyVIKOR and environmental impact analysis for material selection of an automotive component, Materials & Design , vol. 37, pp. 478-486. [10] Grubert, E. (2017) The Need for a Preference-Based Multicriteria Prioritization Framework in Life Cycle Sustainability Assessment., Journal of Industrial Ecology , vol. 21, pp. 1522-1535. [11] Jasiński D., Meredith J. and Kirwan K. (2016). A comprehensive framework for automotive sustainability assessment, Journal of Cleaner Production , vol. 135, pp. 1034-1044. [12] Kiker, G.A., Bridges, T.S., Varghese, A., Seager T.P. and Linkov I. (2005). Application of multicriteria decision analysis in environmental decision making. Integrated Environmental Assessment and Management., vol.1, pp. 95-108. [13] Kloepffer, W. (2008). Life cycle sustainability assessment of products. The International Journal of Life Cycle Assessment , vol. 13, pp. 89-95. [14] Lenort R. and Wicher P. (2013). Concept of a system for resilience measurement in industrial supply chain, In 22nd International Conference on Metallurgy and Materials METAL 2013 , Brno.

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