Abstract
Transport makes up 20 percent of the World’s energy use; in OECD countries this has exceeded 30 percent. The International Energy Agency (IEA) estimates that the global energy consumption will increase by 2.1 percent annually, a growth rate that is higher than for any other sector. The high energy consumption means that transportation accounts for nearly 30 percent of CO2 emission in OECD countries and is also one of the main sources of regional and local air pollution. In this article, we analyze energy consumption and greenhouse gas emissions from passenger car transport using an energy chain analysis. The energy chain analysis consists of three parts: the net direct energy use, the energy required for vehicle propulsion; the gross direct chain, which includes the net direct energy consumption plus the energy required to produce it; and, finally, the indirect energy chain, which includes the energy consumption for production, maintenance and operation of infrastructure plus manufacturing of the vehicle itself. In addition to energy consumption, we also analyze emissions of greenhouse gases measured by CO2-equivalents. We look at the trade-offs between energy use and greenhouse gas emissions to see whether some drivetrains and fuels perform favourable on both indicators. Except for the case of electric cars, where hydropower is the only energy source in the Norwegian context, no single car scores favourably on both energy consumption and greenhouse gas emissions.
Highlights
Are there trade-offs between energy use and greenhouse gas emissions for different types of passenger cars? In order to answer this question, we have performed an energy chain analysis that addresses three questions: 1. What is the direct energy consumption for the car’s propulsion? What are the corresponding greenhouse gas emissions measured in CO2-equivalents?
In 2010, transport in the EU accounted for a third of total energy consumption and more than a fifth of all greenhouse gas emissions [1]
The growth in volumes is greater than growth in energy efficiency, thereby leading to an increasing impact of transport on greenhouse gas emissions and energy consumption
Summary
2. What are the energy consumption and greenhouse gas emissions associated with the production of propulsion energy?. 3. What are the embodied energy and greenhouse gas emissions for the construction, maintenance, and operation of the passenger car’s infrastructure and of the car itself?. In 2010, transport in the EU accounted for a third of total energy consumption and more than a fifth of all greenhouse gas emissions [1]. The growth in volumes is greater than growth in the energy efficiency, thereby leading to an increasing impact of transport on greenhouse gas emissions. The growth in volumes is greater than growth in energy efficiency, thereby leading to an increasing impact of transport on greenhouse gas emissions and energy consumption
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
