Comparing Power-System- and User-Oriented Battery Electric Vehicle Charging Representation and its Implications on Energy System Modeling

Wulff, Niklas; Steck, Felix; Gils, Hans Christian; Hoyer-Klick, Carsten; Adel, Bent van den; Anderson, John E.

doi:10.20944/preprints202001.0224.v1

Cited by 1 publication

(2 citation statements)

References 19 publications

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“…In addition, increased use of fast chargers in combination with new electric car sharing systems may contribute to more daytime charging in the future (Biondi et al, 2016). While we have quantified emissions associated with predefined, stylized charging patterns, low emission intensities of daytime electricity can in practice also be exploited through controlled ("smart") charging (Coignard et al, 2018;Xu et al, 2020;Wulff et al, 2020) and/or grid-level energy storage (Garcia et al, 2018;Jafari et al, 2020), which are two avenues policy makers can consider. The uncertainties and limitations of the current study-as discussed in the following paragraphs-should be borne in mind when interpreting the results.…”

Section: Discussionmentioning

confidence: 99%

“…Some studies explore hypothetical charging regimes (e.g., Coignard et al, 2018;Tamayao et al, 2015), others derive charging patterns from detailed tests for a small number of vehicles (Rangaraju et al, 2015), from travel surveys covering a larger number of vehicles (Crossin & Doherty, 2016;Jochem et al, 2015) or from data from websites and fleet tests (Plötz et al, 2017). A number of studies examine charging time in the context of electricity supply and demand balancing, but do not quantify emissions (e.g., Babrowski et al, 2014;Coignard et al, 2018;Khoo et al, 2014;Sadeghianpourhamami et al, 2018;Wulff et al, 2020). Other analyses quantify only direct emissions of electricity generation (i.e., emissions occurring in the energy conversion process itself) (Donateo et al, 2015;Ensslen et al, 2017;Jochem et al, 2015), while yet others also consider indirect emissions of electricity (such as emissions occurring in transport of fuels to power plant or manufacturing of power plant infrastructure) (Garcia et al, 2018).…”

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Emissions of electric vehicle charging in future scenarios: The effects of time of charging

Arvesen

Völler

Hung

et al. 2021

J of Industrial Ecology

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Electrification of transport is an important option to reduce greenhouse gas emissions.Although many studies have analyzed emission implications of electric vehicle charging, time-specific emission effects of charging are inadequately understood. Here, we combine climate protection scenarios for Europe for the year 2050, detailed power system simulation at hourly time steps, and life cycle assessment of electricity in order to explore the influence of time on the greenhouse gas emissions associated with electric vehicle charging for representative days. We consider both average and short-term marginal emissions. We find that the mix of electricity generation technologies, and thus, also the emissions of charging, vary appreciably across the 24-h day. In our estimates for Europe for 2050, an assumed day-charging regime yields one-third-to-onehalf lower average emissions than an assumed night-charging regime. This is owing to high fractions of solar PV in the electricity mix during daytime and more reliance on natural gas electricity in the late evening and night. The effect is stronger during summer months than during winter months, with day charging causing one-half-totwo-thirds lower emissions than night charging during summer. Also, when short-term marginal electricity is assumed, emissions tend to be lower with day charging because of contributions from nuclear electricity during the day. However, the results for shortterm marginal electricity have high uncertainty. Overall, our results suggest a need for electric vehicle charging policies and emission assessments to take into consideration variations in electricity mixes and time profiles of vehicle charging over the 24-h day. K E Y W O R D Selectricity scenarios, greenhouse gas emissions, industrial ecology, integrated assessment model, life cycle assessment, power system model INTRODUCTIONSwitching from petroleum-burning transport to transport powered by climate-friendly electricity is an important strategy according to climate stabilization scenarios (Figure 1; Luderer et al., 2016;Tran et al., 2012;Williams et al., 2012). Understanding the current and future emissions associated with electric vehicle charging is a key component to formulating effective electrification strategies (Cox et al., 2018;Ellingsen & Hung, 2018; This is an open access article under the terms of the Creative Commons Attribution-NonCommercial License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes.

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