Potential of e-bikes to replace passenger car trips and reduce greenhouse gas emissions
Journal article, 2024

In Sweden, the transport sector accounts for 32% of greenhouse gas emissions, with passenger cars contributing to 62% of these. In this context, electric bikes, commonly known as e-bikes, have emerged as a promising solution for reducing carbon emissions in the transport sector. This paper explores the potential of e-bikes in substituting passenger car trips and reducing transportation-related emissions. To achieve this objective, we use a synthetic population in the Västra Götaland (VG) region, Sweden, with daily activity schedules and simulate an average weekday of travelling with e-bikes instead of their private cars. For assessing the potential for e-bike substitution, the current literature often relies on trip-level analysis, which does not adequately consider people's daily travel-activity plans, resulting in an unrealistic estimation of replaceable trips and their carbon emissions reduction. Combining an e-bike speed model by agents' characteristics and an open-source routing engine, our simulation identifies potential car trips that can be replaced with e-bikes, considering all activities and the travel between them for an average weekday. The simulation results suggest that e-bikes could replace 57.6% of car trips. Building on this, we explore the potential reduction in greenhouse gas emissions from car trips taken by residents in the study area. If the top 70% of feasible car users, ranked by shortest to longest daily travel distances, switch to e-bikes, emissions could be reduced by 10.1% compared to 2018 levels. If all feasible car users adopt e-bikes, a reduction of up to 22.8% in emissions could be achieved, representing the upper limit presented by our study. The findings also reveal that males under 40 years old provide the highest e-bike substitution rates in their daily activity schedules, and in areas with a high population density, replaceable car trips are more common than in rural areas. This research provides valuable insights into e-bike substitution and its impact on emission reduction. It contributes to the existing literature through its modelling approach that realistically considers individuals' socio-demographic characteristics and daily activity schedules when assessing the substitution potential.

Emissions-reduction

Active mobility

Daily activity-travel plans

E-bike

Synthetic population

Author

Çaglar Tozluoglu

Chalmers, Space, Earth and Environment, Physical Resource Theory

Yuan Liao

Chalmers, Space, Earth and Environment, Physical Resource Theory

Frances Sprei

Chalmers, Space, Earth and Environment, Physical Resource Theory

Journal of Cycling and Micromobility Research

2950-1059 (eISSN)

Vol. 2

Areas of Advance

Transport

Subject Categories

Transport Systems and Logistics

DOI

10.1016/j.jcmr.2024.100043

More information

Created

9/10/2024