US Energy Production Results in $120B Hidden Cost

The "hidden" costs of energy production in the US were estimated at $120 billion dollars in a new report from the National Research Council.

The report examines and, when possible, estimates unaccounted costs of energy production and use–such as the damage air pollution imposes on human health–that are not reflected in market prices of coal, oil, other energy sources, or the electricity and gasoline produced from them. 

The report estimates dollar values for several major components of these costs. The damages the committee was able to quantify were an estimated $120 billion in the U.S. in 2005, a number that reflects primarily health damages from air pollution associated with electricity generation and motor vehicle transportation. The figure does not include damages from climate change, harm to ecosystems, effects of some air pollutants such as mercury, and risks to national security, which the report examines but does not monetize.  

Requested by Congress, the report assesses what economists call external effects caused by various energy sources over their entire life cycle–for example, not only the pollution generated when gasoline is used to run a car but also the pollution created by extracting and refining oil and transporting fuel to gas stations. Because these effects are not reflected in energy prices, government, businesses and consumers may not realize the full impact of their choices. When such market failures occur, a case can be made for government interventions–such as regulations, taxes or tradable permits–to address these external costs, the report says.

The committee that wrote the report focused on monetizing the damage of major air pollutants–sulfur dioxide, nitrogen oxides, ozone, and particulate matter–on human health, grain crops and timber yields, buildings, and recreation. When possible, it estimated both what the damages were in 2005 (the latest year for which data were available) and what they are likely to be in 2030, assuming current policies continue and new policies already slated for implementation are put in place.   

The committee also separately derived a range of values for damages from climate change; the wide range of possibilities for these damages made it impossible to develop precise estimates of cost. However, all model results available to the committee indicate that climate-related damages caused by each ton of CO2 emissions will be far worse in 2030 than now; even if the total amount of annual emissions remains steady, the damages caused by each ton would increase 50% to 80%.

DAMAGES FROM ELECTRICITY GENERATION

Coal accounts for about half the electricity produced in the U.S.  In 2005 the total annual external damages from sulfur dioxide, nitrogen oxides, and particulate matter created by burning coal at 406 coal-fired power plants, which produce 95% of the nation’s coal-generated electricity, were about $62 billion; these nonclimate damages average about 3.2 cents for every kilowatt-hour (kwh) of energy produced.  A relatively small number of plants–10% of the total number–accounted for 43% of the damages.  By 2030, nonclimate damages are estimated to fall to 1.7 cents per kwh.

Coal-fired power plants are the single largest source of greenhouse gases in the U.S., emitting on average about a ton of CO2 per megawatt-hour of electricity produced, the report says. Climate-related monetary damages range from 0.1 cents to 10 cents per kilowatt-hour, based on previous modeling studies.

Burning natural gas generated far less damage than coal, both overall and per kilowatt-hour of electricity generated.  A sample of 498 natural gas fueled plants, which accounted for 71% of gas-generated electricity, produced $740 million in total nonclimate damages in 2005, an average of 0.16 cents per kwh.  As with coal, there was a vast difference among plants; half the plants account for only 4% of the total nonclimate damages from air pollution, while 10% produce 65% of the damages. By 2030, nonclimate damages are estimated to fall to 0.11 cents per kwh. Estimated climate damages from natural gas were half that of coal, ranging from 0.05 cents to 5 cents per kilowatt-hour.

The life-cycle damages of wind power, which produces just over 1% of U.S. electricity but has large growth potential, are small compared with those from coal and natural gas. So are the damages associated with normal operation of the nation’s 104 nuclear reactors, which provide almost 20% of the country’s electricity. But the life cycle of nuclear power does pose some risks; if uranium mining activities contaminate ground or surface water, for example, people could potentially be exposed to radon or other radionuclides; this risk is borne mostly by other nations, the report says, because the U.S. mines only 5% of the world’s uranium. The potential risks from a proposed long-term facility for storing high-level radioactive waste need further evaluation before they can be quantified. Life-cycle CO2 emissions from nuclear, wind, biomass, and solar power appear to be negligible when compared with fossil fuels.

OTHER DAMAGES

The production of heat for buildings or industrial processes accounts for about 30% of American energy demand. Most of this heat energy comes from natural gas or, to a lesser extent, the use of electricity; the total damages from burning natural gas for heat were about $1.4 billion in 2005.

Transportation, which today relies almost exclusively on oil, accounts for nearly 30% of U.S. energy demand. In 2005 motor vehicles produced $56 billion in health and other nonclimate-related damages, says the report.

Damages per vehicle mile traveled were remarkably similar among various combinations of fuels and technologies–the range was 1.2 cents to about 1.7 cents per mile traveled–and it is important to be cautious in interpreting small differences, the report says.

ELECTRIC VEHICLES

Electric vehicles and grid-dependent (plug-in) hybrid vehicles showed somewhat higher nonclimate damages than many other technologies for both 2005 and 2030. Operating these vehicles produces few or no emissions, but producing the electricity to power them currently relies heavily on fossil fuels; also, energy used in creating the battery and electric motor adds up to 20% to the manufacturing part of life-cycle damages.

Most vehicle and fuel combinations had similar levels of greenhouse gas emissions in 2005. There are not substantial changes estimated for those emissions in 2030; while population and income growth are expected to drive up the damages caused by each ton of emissions, implementation of new fuel efficiency standards of 35.5 miles per gallon will lower emissions and damages for every vehicle mile traveled. Achieving significant reductions in greenhouse gas emissions by 2030 will likely also require breakthrough technologies, such as cost-effective carbon capture and storage or conversion of advanced biofuels, the report says.

Both for 2005 and 2030, vehicles using gasoline made from oil extracted from tar sands and those using diesel derived from the Fischer-Tropsch process–which converts coal, methane, or biomass to liquid fuel–had the highest life-cycle greenhouse gas emissions. Vehicles using ethanol made from corn stover or herbaceous feedstock such as switchgrass had some of the lowest greenhouse gas emissions, as did those powered by compressed natural gas.

Fully implementing federal rules on diesel fuel emissions, which require vehicles beginning in the model year 2007 to use low-sulfur diesel, is expected to substantially decrease nonclimate damages from diesel by 2030–an indication of how regulatory actions can significantly affect energy-related damages, the committee said. Major initiatives to further lower other emissions, improve energy efficiency, or shift to a cleaner mix of energy sources could reduce other damages as well, such as substantially lowering the damages attributable to electric vehicles.

The report was sponsored by the U.S. Department of the Treasury, National Academy of Sciences, National Academy of Engineering, Institute of Medicine, and National Research Council make up the National Academies. They are independent, nonprofit institutions that provide science, technology, and health policy advice under an 1863 congressional charter.  Committee members, who serve pro bono as volunteers, are chosen by the Academies for each study based on their expertise and experience and must satisfy the Academies’s conflict-of-interest standards.  The resulting consensus reports undergo external peer review before completion.  For more information, visit http://national-academies.org/studycommitteeprocess.pdf.  A committee roster follows.

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