Help or hindrance? The travel, energy and carbon impacts of highly automated vehicles

Help or hindrance? The travel, energy and carbon impacts of highly automated vehicles

•First order travel, energy and carbon impacts of vehicle automation estimated using a decomposition framework.•Energy use affected via changes in vehicle design, traffic flow efficiency, and travel demand.•Automation can substantially reduce energy consumption and carbon emissions.•Low level of aut...

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Bibliographic Details
Published in:Transportation research. Part A, Policy and practice Policy and practice, 2016-04, Vol.86 (C), p.1-18
Main Authors: Wadud, Zia, MacKenzie, Don, Leiby, Paul
Format: Article
Language:eng
Subjects:
Automation
Automobiles
Automotive engineering
Autonomous cars
Carbon emission
Crashworthiness
ENERGY CONSERVATION, CONSUMPTION, AND UTILIZATION
Energy consumption
Energy demand
Energy use
ENVIRONMENTAL SCIENCES
Estimates
Impact strength
Self-driving vehicle
Travel demand
Vehicle automation
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Summary:•First order travel, energy and carbon impacts of vehicle automation estimated using a decomposition framework.•Energy use affected via changes in vehicle design, traffic flow efficiency, and travel demand.•Automation can substantially reduce energy consumption and carbon emissions.•Low level of automation allows substantial reductions in energy use by improving energy intensity.•High level of automation could nullify these benefits and increase energy use via greater travel. Experts predict that new automobiles will be capable of driving themselves under limited conditions within 5–10years, and under most conditions within 10–20years. Automation may affect road vehicle energy consumption and greenhouse gas (GHG) emissions in a host of ways, positive and negative, by causing changes in travel demand, vehicle design, vehicle operating profiles, and choices of fuels. In this paper, we identify specific mechanisms through which automation may affect travel and energy demand and resulting GHG emissions and bring them together using a coherent energy decomposition framework. We review the literature for estimates of the energy impacts of each mechanism and, where the literature is lacking, develop our own estimates using engineering and economic analysis. We consider how widely applicable each mechanism is, and quantify the potential impact of each mechanism on a common basis: the percentage change it is expected to cause in total GHG emissions from light-duty or heavy-duty vehicles in the U.S. Our primary focus is travel related energy consumption and emissions, since potential lifecycle impacts are generally smaller in magnitude. We explore the net effects of automation on emissions through several illustrative scenarios, finding that automation might plausibly reduce road transport GHG emissions and energy use by nearly half – or nearly double them – depending on which effects come to dominate. We also find that many potential energy-reduction benefits may be realized through partial automation, while the major energy/emission downside risks appear more likely at full automation. We close by presenting some implications for policymakers and identifying priority areas for further research.
ISSN:0965-8564
1879-2375