Sustainable mobility: Challenges for the transition

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Sustainable mobility: Challenges for the transition Amela Ajanovic Energy Economics Group Vienna University of Technology Milan, 10-12 December 2018

Content Introduction Historical developments Policy framework Standards vs. taxes Electric vehicles Conclusion

Introduction Basic principle: Service: km driven S=f(E, η (Tc), η (Tis)) Fuel mix, Fuel demand Efficiency: Liter/100 km Infrastructur

Introduction Amount of transport services per capita Horse power Sailing ship based on non-commercial renewable energy based on commercial energy Electricity, combustion Steam engine machine, steam railway time

Transport sector 93% oil products' share of final energy consumption for transport, making the sector the leastdiversified Countries with largest conventional oil reserves

Final energy consumption by sector in the EU, 2015

Final energy consumption by sector 2015 in the EU

GHG emissions in EU 28 IEA,2017

The challenges for EU climate and energy policies Mitigate global warming Improve air quality Car passenger transport Reduce energy consumption Effective policies and measures

EU targets 20-20-20 40-27-27 10% ICE -50% in city No ICE in city 2009 2010 2015 2020 2030 2050 130 gco2/km 20% GHG (2008) 60% GHG (1990) 95 gco2/km The White Paper on Transport Policy Targets and average CO 2 emissions from new passenger cars in EU countries

Electric vehicles Paris Declaration on Electro-Mobility and Climate Change & Call to Action: more than 100 million EVs 400 million two and three-wheelers

CO 2 emissions in passenger car transport CO 2 emissions Energy x = x CO 2 emissions coefficient = On-road power-specific x Total vkm fuel efficiency driven = Test-cycle fuel x Driving coefficient intensity behaviour x Power (capacity) of car to be reduced e.g. by kw-specific registration tax lower coefficient for biofuels or electricity to be improved by automobile manufacture to be reduced by eco-driving to be influenced by fuel taxes or fuel intensity improvements Standards Education Fuel tax Registration tax Subsidies, quotas Policy instruments Impact factors on CO 2 emissions in the car passenger transport sector

Standards USA, Canada 2025: 103 gco2/km EU 2021: 95 gco2/km China 2020: 117 gco2/km Japan 2020: 105 gco2/km India 2021: 113 gco2/km

Standards Next targets 2025. average emissions 15% lower than in 2021 2030 average emissions 30% lower than in 2021 Test procedure: New European Driving Cycle (NEDC) Worldwide Harmonised Light Vehicle Test Procedure (WLTP)

Fuel taxes in the EU

Tax vs. standard Price of service P t Preis (p) der EDL Fiscal measure (tax) P 0 P s Technical measure ΔE E 1 E 0 η 1 η 0 Energieverbrauch kwh Energy consumption

Rebound effect 2 2 th 2 pr 1 1 S 2 =vkm 2 E REB E pr save S 1 =vkm 1 E th 2 E pr 2 E 1 E E th save

Standards & taxes Ps Ps 0 =Ps 2 1 new efficiency Tax effect 0 old efficiency Efficiency effect Ps 1 E 2 ΔE tax E 1 ΔE η E 0 E How taxes and standards interact and how they can be implemented in a combined optimal way for society

Electric vehicles

Environmental assessment Well-to-Wheel (WTW) Primary energy source Fuel TTW_fuel Mobility Car TTW_car Well-to-Tank (WTT) Tank-to-Wheel (TTW)

Environmental assessment CO 2 emissions per km driven for various types of EV in comparison to conventional cars (power of car: 80kW)

Car-oriented mobility

Mobility Car-oriented transport development https://simotron.files.wordpress.com

Strategies for energy efficient mobility Energy efficiency of mobility System efficiency Travel efficiency Vehicle efficiency AVOID unnecessary travel and reduce trip distances SHIFT towards more sustainable modes IMPROVE transport practices and technologies

Conclusions Policy framework not sufficient Standards. rebound effect a harmonization of taxes in EU countries and their adaptation to the CO 2 targets..contribution to the reduction of the negative impacts of the rebound effect Electric vehicles new policy design Systematic approach

ajanovic@eeg.tuwien.ac.at