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| 1 |
ID:
091524
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2009.
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| Summary/Abstract |
In 2006, energy-related CO2 emissions from transport energy in Ireland were 168% above 1990 levels. Private cars were responsible for approx 45% of transport energy demand in 2006 (excluding fuel tourism). The average annual growth of new cars between 1990 and 2006 was 5.2%. This paper focuses on these new cars entering the private car fleet, in particular the purchasing trend towards larger size cars. This has considerably offset the improvements in the technical efficiency of individual car models. The analysis was carried out on the detailed data of each individual new vehicle entering the fleet in 2000-2006. The average CO2 emissions per kilometre for new petrol cars entering the Irish fleet grew from 166 to 168 g CO2/km from 2000 to 2005 and reduced to 164 in 2006. For diesel cars the average reduced from 166 in 2000 to 161 in 2006. The paper also discusses how a recent change in vehicle registration taxation and annual motor tax had a significant impact purchasing trends by supporting lower emission vehicles. Cars with emissions up to 155 g CO2/km represented 41% of new private cars sold in Ireland in 2007 compared with 84% during the period July-November 2008.
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| 2 |
ID:
150645
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The transit authority in Perth, Western Australia, has put several alternative fuel buses, including diesel-electric hybrid and hydrogen fuel cell buses, into revenue service over the years alongside conventional diesel and natural gas buses. Primary data from this fleet is used to construct a Life Cycle Cost (LCC) model, providing an empirical LCC result. The model is then used to forecast possible scenarios using cost estimates for next generation technologies. The methodology follows the Australian/New Zealand Standard for Life Cycle Costing, AS/NZS 4536:1999. The model outputs a dollar value in real terms that represents the LCC of each bus transportation technology. The study finds that Diesel buses deliver the lowest Total Cost of Ownership (TCO). The diesel-electric hybrid bus was found to have a TCO that is about 10% higher than conventional diesel. The premium to implement and operate a hydrogen bus, even if industry targets are attained, is still substantially greater than the TCO of a conventional diesel bus, unless a very large increase in the diesel fuel price occurs. However, the hybrid and hydrogen technologies are still very young in comparison to diesel and economies of scale are yet to be realised.
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| 3 |
ID:
096726
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2010.
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| Summary/Abstract |
Having a clear understanding of transport energy use trends is crucial to identifying opportunities and challenges for efficient energy use for the transport sector. To this date, however, no detailed analysis has been conducted with regard to rapidly growing passenger transport energy use in South Korea. Using bottom-up data developed from a variety of recent sources, we described the trends of transport activity, energy use, and CO2 emissions from South Korea's transport sector since 1986 with a particular focus on its passenger transport. By decomposing the trends in passenger transport energy use into activity, modal structure, and energy intensity, we showed that while travel activity has been the major driver of the increase in passenger transport energy use in South Korea, the increase was to some extent offset by the recent favorable structural shift toward bus travel and away from car travel. We also demonstrated that while bus travel has become less energy intensive since the Asian Financial Crisis, car travel has become increasingly energy intensive.
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| 4 |
ID:
097526
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| Publication |
2010.
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| Summary/Abstract |
Having a clear understanding of transport energy use trends is crucial to identifying opportunities and challenges for efficient energy use for the transport sector. To this date, however, no detailed analysis has been conducted with regard to rapidly growing passenger transport energy use in South Korea. Using bottom-up data developed from a variety of recent sources, we described the trends of transport activity, energy use, and CO2 emissions from South Korea's transport sector since 1986 with a particular focus on its passenger transport. By decomposing the trends in passenger transport energy use into activity, modal structure, and energy intensity, we showed that while travel activity has been the major driver of the increase in passenger transport energy use in South Korea, the increase was to some extent offset by the recent favorable structural shift toward bus travel and away from car travel. We also demonstrated that while bus travel has become less energy intensive since the Asian Financial Crisis, car travel has become increasingly energy intensive.
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