Economy advantage

Transportation infrastructure emits and facilitates emissions

Emissions scenarios such as those produced by the Intergovernmental Panel on Climate Change (IPCC) rely on projected changes in population, economic growth, energy demand, and the carbon intensity of energy over time (8). Although these scenarios represent plausible future emissions trends, the infrastructural inertia of emissions at any point in time is not explicitly quantified. Here, we present scenarios reflecting direct emissions from existing energy and transportation infrastructure, along with climate model results showing the warming commitment of these emissions. With respect to GHG emissions, infrastructural inertia may be thought of as having two important and overlapping components: (i) infrastructure that directly releases GHGs to the atmosphere, and (ii) infrastructure that contributes to the continued production of devices that emit GHGs to the atmosphere. For example, the interstate highway and refueling infrastructure in the United States facilitates continued production of gasoline powered automobiles. Here, we focus only on the warming commitment from infrastructure that directly releases CO2 to the atmosphere. Essentially, we answer the following question: What if no additional CO2-emitting devices (e.g., power plants, motor vehicles) were built, but all the existing CO2-emitting devices were allowed to live out their normal lifetimes? What CO2 levels and global mean temperatures would we attain? Of course, the actual lifetime of devices may be strongly influenced by economic and policy constraints. For instance, a ban on new CO2-emitting devices would create tremendous incentive to prolong the lifetime of existing devices. Thus, our scenarios are not realistic, but they offer a means of gauging the threat of climate change from existing devices relative to those devices that have yet to be built.

Materials for construction emit large amounts of CO2

ADB, July 2010, Evaluation Knowledge Brief, “Reduction Carbon Emissions from Transport Projects” Asian Development Bank Reference Number: EKB: REG 2010-16 http://www.oecd.org/dataoecd/18/46/47170274.pdf
Table 1 shows the carbon emissions contributions by each transport mode. The initial estimate of the overall carbon footprint of ADB’s transport sector assistance approved between 2000 and 2009 is 792 million tons, covering both construction and operations emissions. This is the aggregate carbon footprint of 78,983 km of infrastructure development using ADB's assistance. To put this cumulative total of emissions into perspective, the set of ADB transport projects approved between 2000 and 2009 is estimated to account for 39.6 million tons of CO2 per year, which could be comparable to the annual land transport emissions of Thailand (44 million tons CO2 in 2005) (footnote 17). The quantum of emissions from ADB's transport projects is about 2% of the United States of America's (USA’s) annual transport emissions for 2008.33 Table 1 shows the relative intensity of the carbon footprint as well as the gross carbon emissions. Typically, ADB-funded projects tend to increase or rehabilitate the size of the transport infrastructure, e.g., an expressway project will increase the number of lanes of an existing two-lane highway to a four-lane expressway. The number of lanes has a significant impact on the total carbon footprint as it influences the demand, volume to capacity (V–C) ratios, speed, and construction emissions. The size of the construction emissions varies between 1.2% and 24.0% of total (construction + operations) emissions. This estimate is based on the quantity of three key construction materials used—cement, steel, and bitumen. Although in absolute terms the construction emissions of ADB-funded rural roads are low, they form about 24% of total emissions in this category since the operations emissions are also low. Construction emissions of ADB-funded railway projects are about 2.4% of total emissions in this category. Expressways account for over 60% of ADB’s transportation project-related emissions, 483 million tons, as nearly 22,000 lane-km of expressways were financed by ADB during the period, and these facilities generally produce a high level of CO2 per km. Railways account for most of the rest, about 32%, which is a function of the high tonnage of bulk and other freight carried per track-km of rail—this adds up to considerable energy use even if railways are considerably more energy-efficient per ton-km than trucks for freight haulage. Road rehabilitation projects on average have a small carbon footprint since they do little to induce new traffic, and they improve vehicle operating efficiency. Although these road rehabilitation projects formed 82% of the total km of transport facilities financed for construction or reconstruction by ADB during the past 10 years, they contributed to 4% of the CO2 footprint of ADB’s transport portfolio. Rural road capacity expansion projects typically have only a modest carbon footprint, and these projects made up 4% of the km of transport facilities improved by ADB during the period, so overall emissions from these were also small. ADB had only marginal investments in other types of transport facilities—BRT, MRT, and nonmotorized facilities—during 2000–2009.

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