Environment
U.S. Energy-Related Carbon Dioxide Emissions, 2013
Release Date: October 21, 2014 | Next Release Date: October 2015 | full report
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U.S. Energy-related carbon dioxide emissions increased 2.5% in 2013
Note: All data in this analysis refers to the Monthly Energy Review of September 2014 unless otherwise indicated. Because of slightly differing coverage and data vintage, percent changes may differ slightly with other U.S. Energy Information Administration (EIA) publications. Data on heating and cooling degree days are from the Short-Term Energy Outlook, October 2014.
Energy intensity was the big difference when compared with trendEmissions trends reflect a combination of economic factors:
The sum of the changes in these factors approximates the change in total energy-related CO2. In 2013, several of these factors varied from the trend of the previous decade and this led to the emissions increase. An increase in energy intensity of 0.5% was a leading cause of the 2013 increase in energy-related CO2 emissions when compared with the trend from the prior decade (2003-12), which was -2.0%.
A reversal from the mild heating season of 2012 increased residential energy demand and related emissions in 2013Weather played an important role in the year-to-year increase in CO2 emissions. Residential emissions were up the most of any sector -- 62 MMmt or 48% of the total emissions increase across sectors.
Residential emissions increased from both direct use and electricity-related energyResidential sector electricity consumption was higher in 2013 than in 2012, however direct use of heating fuels increased by a greater percentage.
The commercial sector saw the next largest increase in energy consumption and related CO2 emissionsAfter the residential sector, the next biggest increase in CO2 emissions was from the commercial sector – 36 MMmt or 28% of the total increase.
The overall increase in the carbon intensity of the U.S. economy was slight in 2013The combined increase in energy use per dollar of GDP (0.5%) minus the reduced carbon intensity of the energy supply (-0.3%) meant that the overall carbon intensity of the economy (CO2 per dollar of GDP) increased about 0.2% in 2013.
A 2013 rise in natural gas prices shifted some plant dispatch decisions, resulting in more coal-fired generationBecause the generation of electricity, which is widely used in all sectors except transportation, is an important source of emissions, changes in the carbon intensity of electricity generation affects emissions throughout the economy.
The power sector has helped to stabilize overall energy-related carbon dioxide emissions since 2005Despite the uptick in emissions in 2013, there has been an overall decrease in energy-related CO2 since 2005. The electric power sector has contributed to this.
Increased use of natural gas and the growth in renewables have contributed to the decline in power sector carbon intensity
Implications of the carbon dioxide emissions increase in 2013 for future emissionsIt is difficult to draw conclusions from one year of data. Specific circumstances such as the 18.5% increase in heating degree days between 2012 and 2013 and the increase in coal in the generation mix relative to 2012 affected the year-to-year change. In the longer term, other factors, such as improvements in vehicle fuel efficiency and increased use of renewable generation, could play a continuing role in subsequent years and help to mitigate future emissions growth. For EIA projections on emissions and their key drivers see either the Short-Term Energy Outlook, updated monthly with projections through 2015 (2016 beginning in January 2015) or the Annual Energy Outlook (AEO), with annual projections through 2040. EIA's International Energy Outlook (IEO) contains current projections of international energy consumption and emissions through 2040. The analysis of energy-related carbon dioxide emissions presented here is based on the data in the Monthly Energy Review (MER). The MER reports monthly U.S. energy-related carbon dioxide emissions in Chapter 12 derived from our monthly energy data. For the full range of EIA's emissions products see the Environment page.
Terms used in this analysis: British thermal unit (Btu): The quantity of heat required to raise the temperature of 1 pound of liquid water by 1 degree Fahrenheit at the temperature at which water has its greatest density (approximately 39 degrees Fahrenheit). Carbon intensity (economy): The amount of carbon by weight emitted per unit of economic activity. It is most commonly applied to the economy as a whole, where output is measured as the gross domestic product (GDP). The carbon intensity of the economy is the product of the energy intensity of the economy and the carbon intensity of the energy supply. Note: this value is currently measured using the full weight of the carbon dioxide emitted (CO2/GDP). Carbon intensity (energy supply): The amount of carbon by weight emitted per unit of energy consumed. A common measure of carbon intensity is weight of carbon per Btu of energy. When there is only one fossil fuel under consideration, the carbon intensity and the emissions coefficient are identical. When there are several fuels, carbon intensity is based on their combined emissions coefficients weighted by their energy consumption levels. Note: this value is currently measured using the full weight of the carbon dioxide emitted (CO2/energy or CO2/Btu). Cooling degree days (CDD): A measure of how warm a location is over a period of time relative to a base temperature, most commonly specified as 65 degrees Fahrenheit. The measure is computed for each day by subtracting the base temperature (65 degrees) from the average of the day's high and low temperatures, with negative values set equal to zero. Each day's cooling degree days are summed to create a cooling degree day measure for a specified reference period. Cooling degree days are used in energy analysis as an indicator of air conditioning energy requirements or use. Energy intensity: A measure relating the output of an activity to the energy input to that activity. It is most commonly applied to the economy as a whole, where output is measured as the gross domestic product (GDP) and energy is measured in Btu to allow for the summing of all energy forms (energy/GDP or Btu/GDP). On an economy-wide level, it is reflective of both energy efficiency as well as the structure of the economy. Economies in the process of industrializing tend to have higher energy intensities than economies that are in their post-industrial phase. The term energy intensity can also be used on a smaller scale to relate, for example, the amount of energy consumed in buildings to the amount of residential or commercial floor space. Gross domestic product (GDP): The total value of goods and services produced by labor and property located in the United States. As long as the labor and property are located in the United States, the supplier (that is, the workers and, for property, the owners) may be either U.S. residents or residents of foreign countries. Heating degree days (HDD): A measure of how cold a location is over a period of time relative to a base temperature, most commonly specified as 65 degrees Fahrenheit. The measure is computed for each day by subtracting the average of the day's high and low temperatures from the base temperature (65 degrees), with negative values set equal to zero. Each day's heating degree days are summed to create a heating degree day measure for a specified reference period. Heating degree days are used in energy analysis as an indicator of space heating energy requirements or use. For other definitions see the EIA glossary. Note: This analysis uses MMmt as the abbreviation for million metric tons. This abbreviation is used for consistency with other EIA abbreviations – e.g., million short tons (MMst). |