Climate Change Indicators in the United States: Atmospheric Concentrations of
Greenhouse Gases - www.epa.gov/climatechange/indicators - Updated May 2014
Atmospheric Concentrations of Greenhouse Gases
This indicator describes how the levels of major greenhouse gases in the atmosphere have changed
over time.
Background
Since the Industrial Revolution began in the 1700s, people have added a substantial amount of
greenhouse gases into the atmosphere by burning fossil fuels, cutting down forests, and conducting
other activities (see the U.S. and Global Greenhouse Gas Emissions indicators). When greenhouse gases
are emitted into the atmosphere, many remain there for long time periods ranging from a decade to
many millennia. Over time, these gases are removed from the atmosphere by chemical reactions or by
emissions sinks, such as the oceans and vegetation, which absorb greenhouse gases from the
atmosphere. However, as a result of human activities, these gases are entering the atmosphere more
quickly than they are being removed, and thus their concentrations are increasing.
Carbon dioxide, methane, nitrous oxide, and certain manufactured gases called halogenated gases
(gases that contain chlorine, fluorine, or bromine) become well mixed throughout the global
atmosphere because of their relatively long lifetimes and because of transport by winds. Concentrations
of these greenhouse gases are measured in parts per million (ppm), parts per billion (ppb), or parts per
trillion (ppt) by volume. In other words, a concentration of 1 ppb for a given gas means there is one
molecule of that gas in every 1 billion molecules of air. Some halogenated gases are considered major
greenhouse gases due to their very high global warming potentials and long atmospheric lifetimes even
if they only exist at a few ppt (see the table in the Web version of this indicator for comparison).
Ozone is also a greenhouse gas, but it differs from other
greenhouse gases in several ways. The effects of ozone
depend on its altitude, or where the gas is located
vertically in the atmosphere. Most ozone naturally exists in
the layer of the atmosphere called the stratosphere, which
ranges from approximately 6 to 30 miles above the Earth's
surface. Ozone in the stratosphere has a slight net warming
effect on the planet, but it is good for life on Earth because
it absorbs harmful ultraviolet radiation from the sun,
preventing it from reaching the Earth's surface. In the troposphere—the layer of the atmosphere near
ground level—ozone is an air pollutant that is harmful to breathe, a main ingredient of urban smog, and
an important greenhouse gas that contributes to climate change (see the Climate Forcing indicator).
Unlike the other major greenhouse gases, tropospheric ozone only lasts for days to weeks, so levels
often vary by location and by season.
About the Indicator
This indicator describes concentrations of greenhouse gases in the atmosphere. It focuses on the major
greenhouse gases that result from human activities.
&EPA
This indicator looks at global average
levels of ozone in both the
stratosphere and troposphere. For
trends in ground-level ozone
concentrations within the United
States, see EPA's National Air Quality
Trends Report at:
www.epa.gov/airtrends.
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Climate Change Indicators in the United States: Atmospheric Concentrations of
Greenhouse Gases - www.epa.gov/climatechange/indicators - Updated May 2014
For carbon dioxide, methane, nitrous oxide, and halogenated gases, recent measurements come from
monitoring stations around the world, while measurements of older air come from air bubbles trapped
in layers of ice from Antarctica and Greenland. By determining the age of the ice layers and the
concentrations of gases trapped inside, scientists can learn what the atmosphere was like thousands of
years ago.
This indicator also shows data from satellite instruments that measure ozone density in the
troposphere, the stratosphere, and the "total column," or all layers of the atmosphere. These satellite
data are routinely compared with ground-based instruments to confirm their accuracy. Ozone data have
been averaged worldwide for each year to smooth out the regional and seasonal variations.
Key Points
• Global atmospheric concentrations of carbon dioxide, methane, nitrous oxide, and certain
manufactured greenhouse gases have all risen significantly over the last few hundred years (see
Figures 1, 2, 3, and 4).
• Historical measurements show that the current global atmospheric concentrations of carbon
dioxide, methane, and nitrous oxide are unprecedented compared with the past 800,000 years
(see Figures 1, 2, and 3).
• Carbon dioxide concentrations have increased steadily since the beginning of the industrial era,
rising from an annual average of 280 ppm in the late 1700s to 396 ppm at Mauna Loa in 2013—a
41 percent increase (see Figure 1). Almost all of this increase is due to human activities.1
• The concentration of methane in the atmosphere has more than doubled since preindustrial
times, reaching approximately 1,800 ppb in 2013 (see the range of measurements in Figure 2).
This increase is predominantly due to agriculture and fossil fuel use.2
• Over the past 800,000 years, concentrations of nitrous oxide in the atmosphere rarely exceeded
280 ppb. Levels have risen since the 1920s, however, reaching a new high of 326 ppb in 2013
(average of three sites in Figure 3). This increase is primarily due to agriculture.3
• Concentrations of many of the halogenated gases shown in Figure 4 were essentially zero a few
decades ago but have increased rapidly as they have been incorporated into industrial products
and processes. Some of these chemicals have been or are currently being phased out of use
because they are ozone-depleting substances, meaning they also cause harm to the Earth's
protective ozone layer. As a result, concentrations of many major ozone-depleting gases have
begun to stabilize or decline (see Figure 4, left panel). Concentrations of other halogenated
gases have continued to rise, however, especially where the gases have emerged as substitutes
for ozone-depleting chemicals (see Figure 4, right panel).
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• Overall, the total amount of ozone in the atmosphere decreased by about 3 percent between
1979 and 2013 (see Figure 5). All of the decrease happened in the stratosphere, with most of
the decrease occurring between 1979 and 1994. Changes in stratospheric ozone reflect the
effect of ozone-depleting substances. These chemicals have been released into the air for many
years, but recently, international efforts have reduced emissions and phased out their use.
• Globally, the amount of ozone in the troposphere increased by about 4 percent between 1979
and 2013 (see Figure 5).
&EPA
Water Vapor as a Greenhouse Gas
Water vapor is the most abundant greenhouse gas in the atmosphere. Human activities have
only a small direct influence on atmospheric concentrations of water vapor, primarily through
irrigation and deforestation, so it is not included in this indicator. However, the surface
warming caused by human production of other greenhouse gases leads to an increase in
atmospheric water vapor, because warmer temperatures make it easier for water to evaporate
and stay in the air in vapor form. This creates a positive "feedback loop" in which warming
leads to more warming.
Figure 1. Global Atmospheric Concentrations of Carbon Dioxide Over Time
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Year
This figure shows concentrations of carbon dioxide in the atmosphere from hundreds of thousands of
years ago through 2013, measured in parts per million (ppm). The data come from a variety of historical
ice core studies and recent air monitoring sites around the world. Each line represents a different data
source.
Data source: Compilation of 10 underlying datasets4
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d% Climate Change Indicators in the United States: Atmospheric Concentrations of
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Figure 2. Global Atmospheric Concentrations of Methane Over Time
800,000 BC to 2013 AD
1950 to 2013 AD
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01" Greenhouse Gases - www.epa.gov/climatechange/indicators - Updated May 2014
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Figure 3. Global Atmospheric Concentrations of Nitrous Oxide Over Time
-8. 350
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1950 I960 1970 1980 1990 2000 2010 2020
Year
This figure shows concentrations of nitrous oxide in the atmosphere from hundreds of thousands of years
ago through 2013, measured in parts per billion (ppb). The data come from a variety of historical ice core
studies and recent air monitoring sites around the world. Each line represents a different data source.
Data source: Compilation of six underlying datasets0
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Climate Change Indicators in the United States: Atmospheric Concentrations of
Greenhouse Gases - www.epa.gov/climatechange/indicators - Updated May 2014
Figure 4. Global Atmospheric Concentrations of Selected Halogenated
Gases, 1978-2012
Ozone-depleting substances
Other halogenated gases
HCFC-22
0.1 0.1 '
1975 1985 1995 2005 2015 1975 1985 1995 2005 2015
Year
This figure shows concentrations of several halogenated gases (which contain fluorine, chlorine, or
bromine) in the atmosphere, measured in parts per trillion fppt). The data come from monitoring sites
around the world. Note that the scale increases by factors of 10. This is because the concentrations of
different halogenated gases can vary by a few orders of magnitude. The numbers following the name of
each gas (e.g., HCFC-22) are used to denote specific types of those particular gases.
Data sources: AG AGE, 2014;7 Arnold, 2013;8 NOAA, 20139
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d% Climate Change Indicators in the United States: Atmospheric Concentrations of
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Figure 5. Global Atmospheric Concentrations of Ozone, 1979-2013
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300
250
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Total column
Stratosphere
Troposphere
1985 1990
1995
Year
2000
2005
2010
This figure shows the average amount of ozone in the Earth's atmosphere each year, based on satellite
measurements. The total represents the "thickness" or density of ozone throughout all layers of the
Earth's atmosphere, which is called total column ozone and measured in Dobson units. Higher numbers
indicate more ozone. For most years, Figure 5 shows how this ozone is divided between the troposphere
(the part of the atmosphere closest to the ground) and the stratosphere. From 1994 to 1996, only the
total is available, due to limited satellite coverage.
Data sources: NASA, 2013,10 201411'12
Indicator Notes
This indicator includes several of the most important halogenated gases, but some others are not
shown. Many other halogenated gases are also greenhouse gases, but Figure 4 is limited to a set of
common examples that represent most of the major types of these gases. The indicator also does not
address certain other pollutants that can affect climate by either reflecting or absorbing energy. For
example, sulfate particles can reflect sunlight away from the Earth, while black carbon aerosols (soot)
absorb energy. Data for nitrogen trifluoride (Figure 4) reflect modeled averages based on measurements
made in the Northern Hemisphere and some locations in the Southern Hemisphere, to represent global
average concentrations over time. The global averages for ozone only cover the area between 50°N and
50°S latitude (77 percent of the Earth's surface), because at higher latitudes the lack of sunlight in winter
creates data gaps and the angle of incoming sunlight during the rest of the year reduces the accuracy of
the satellite measuring technique.
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Climate Change Indicators in the United States: Atmospheric Concentrations of
Greenhouse Gases - www.epa.gov/climatechange/indicators - Updated May 2014
Data Sources
Global atmospheric concentration measurements for carbon dioxide (Figure 1), methane (Figure 2), and
nitrous oxide (Figure 3) come from a variety of monitoring programs and studies published in peer-
reviewed literature. Global atmospheric concentration data for selected halogenated gases (Figure 4)
were compiled by the Advanced Global Atmospheric Gases Experiment, the National Oceanic and
Atmospheric Administration, and a peer-reviewed study on nitrogen trifluoride. A similar figure with
many of these gases appears in the Intergovernmental Panel on Climate Change's Fifth Assessment
Report.13 Satellite measurements of ozone were processed by the National Aeronautics and Space
Administration and validated using ground-based measurements collected by the National Oceanic and
Atmospheric Administration.
1 IPCC (Intergovernmental Panel on Climate Change). 2013. Climate change 2013: The physical science basis.
Working Group I contribution to the IPCC Fifth Assessment Report. Cambridge, United Kingdom: Cambridge
University Press, www.ipcc.ch/report/ar5/wgl.
2 IPCC (Intergovernmental Panel on Climate Change). 2013. Climate change 2013: The physical science basis.
Working Group I contribution to the IPCC Fifth Assessment Report. Cambridge, United Kingdom: Cambridge
University Press, www.ipcc.ch/report/ar5/wgl.
3 IPCC (Intergovernmental Panel on Climate Change). 2013. Climate change 2013: The physical science basis.
Working Group I contribution to the IPCC Fifth Assessment Report. Cambridge, United Kingdom: Cambridge
University Press, www.ipcc.ch/report/ar5/wgl.
4 [see full list provided on next page]
5 [see full list provided on next page]
6 [see full list provided on next page]
7 AGAGE (Advanced Global Atmospheric Gases Experiment). 2014. ALE/GAGE/AGAGE data base. Accessed May
2014. http://agage.eas.gatech.edu/data.htm.
8 Arnold, T. 2013 update to data originally published in: Arnold, T., C.M. Harth, J. Miihle, A.J. Manning, P.K.
Salameh, J. Kim, D.J. Ivy, LP. Steele, V.V. Petrenko, J.P. Severinghaus, D. Baggenstos, and R.F. Weiss. 2013.
Nitrogen trifluoride global emissions estimated from updated atmospheric measurements. P. Natl. Acad. Sci.
USA 110(6):2029-2034. Data updated May 2013.
9 NOAA (National Oceanic and Atmospheric Administration). 2013. Halocarbons and Other Atmospheric Trace
Species group (HATS). Accessed July 2013. www.esrl.noaa.gov/gmd/hats.
10 NASA (National Aeronautics and Space Administration). 2013. Data—TOMS/SBUV TOR data products. Accessed
November 2013. http://science.larc.nasa.gov/TOR/data.html.
11 NASA (National Aeronautics and Space Administration). 2014. SBUV merged ozone data set (MOD). Version 8.6.
Pre-online release provided by NASA staff, May 2014. http://acdb-
ext.gsfc.nasa.gov/Data services/merged/index.htm I.
12 NASA (National Aeronautics and Space Administration). 2014. Tropospheric ozone data from AURA OMI/MLS.
Accessed May 2014. http://acdb-ext.gsfc.nasa.gov/Data services/cloud slice/new data.html.
13 IPCC (Intergovernmental Panel on Climate Change). 2013. Climate change 2013: The physical science basis.
Working Group I contribution to the IPCC Fifth Assessment Report. Cambridge, United Kingdom: Cambridge
University Press, www.ipcc.ch/report/ar5/wgl.
&EPA
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Atmospheric Concentrations of Greenhouse Gases: Citations for Figures 1, 2, and 3
Figure 1
EPICA Dome C and Vostok Station, Antarctica: approximately 796,562 BC to 1813 AD
Liithi, D., M. Le Floch, B. Bereiter, T. Blunier, J.-M. Barnola, U. Siegenthaler, D. Raynaud, J. Jouzel, H.
Fischer, K. Kawamura, and T.F. Stocker. 2008. High-resolution carbon dioxide concentration record
650,000-800,000 years before present. Nature 453:379-382.
www.ncdc.noaa.gov/paleo/pubs/luethi2008/luethi2008.html.
Law Dome, Antarctica, 75-year smoothed: approximately 1010 AD to 1975 AD
Etheridge, D.M., L.P. Steele, R.L. Langenfelds, R.J. Francey, J.M. Barnola, and V.I. Morgan. 1998.
Historical C02 records from the Law Dome DE08, DE08-2, and DSS ice cores. In: Trends: A compendium
of data on global change. Oak Ridge, TN: U.S. Department of Energy. Accessed September 14, 2005.
http://cdiac.ornl.gov/trends/co2/lawdome.html.
Siple Station, Antarctica: approximately 1744 AD to 1953 AD
Neftel, A., H. Friedli, E. Moor, H. Lotscher, H. Oeschger, U. Siegenthaler, and B. Stauffer. 1994. Historical
carbon dioxide record from the Siple Station ice core. In: Trends: A compendium of data on global
change. Oak Ridge, TN: U.S. Department of Energy. Accessed September 14, 2005.
http://cdiac.ornl.gov/trends/co2/siple.html.
Mauna Loa, Hawaii: 1959 AD to 2013 AD
NOAA (National Oceanic and Atmospheric Administration). 2014. Annual mean carbon dioxide
concentrations for Mauna Loa, Hawaii. Accessed April 7, 2014.
ftp://ftp.cmdl.noaa.gov/products/trends/co2/co2 annmean mlo.txt.
Barrow, Alaska: 1974 AD to 2012 AD
Cape Matatula, American Samoa: 1976 AD to 2012 AD
South Pole, Antarctica: 1976 AD to 2012 AD
NOAA (National Oceanic and Atmospheric Administration). 2014. Monthly mean carbon dioxide
concentrations for Barrow, Alaska; Cape Matatula, American Samoa; and the South Pole. Accessed April
7, 2014. ftp://ftp.cmdl.noaa.gov/data/trace gases/co2/in-situ.
Cape Grim, Australia: 1992 AD to 2006 AD
Shetland Islands, Scotland: 1993 AD to 2002 AD
Steele, L.P., P.B. Krummel, and R.L. Langenfelds. 2007. Atmospheric C02 concentrations (ppmv) derived
from flask air samples collected at Cape Grim, Australia, and Shetland Islands, Scotland. Commonwealth
Scientific and Industrial Research Organisation. Accessed January 20, 2009.
http://cdiac.esd.ornl.gov/ftp/trends/co2/csiro.
Lampedusa Island, Italy: 1993 AD to 2000 AD
Chamard, P., L. Ciattaglia, A. di Sarra, and F. Monteleone. 2001. Atmospheric carbon dioxide record from
flask measurements at Lampedusa Island. In: Trends: A compendium of data on global change. Oak
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d% Climate Change Indicators in the United States: Atmospheric Concentrations of
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Ridge, TN: U.S. Department of Energy. Accessed September 14, 2005.
http://cdiac.ornl.gov/trends/co2/lampis.html.
Figure 2
EPICA Dome C, Antarctica: approximately 797,446 BC to 1937 AD
Loulergue, L., A. Schilt, R. Spahni, V. Masson-Delmotte, T. Blunier, B. Lemieux, J.-M. Barnola, D. Raynaud,
T.F. Stocker, and J. Chappellaz. 2008. Orbital and millennial-scale features of atmospheric CH4 over the
past 800,000 years. Nature 453:383-386.
www.ncdc.noaa.gov/paleo/pubs/loulergue2008/loulergue2008.html.
Law Dome, Antarctica: approximately 1008 AD to 1980 AD
Etheridge, D.M., L.P. Steele, R.J. Francey, and R.L. Langenfelds. 2002. Historic CH4 records from Antarctic
and Greenland ice cores, Antarctic firn data, and archived air samples from Cape Grim, Tasmania. In:
Trends: A compendium of data on global change. Oak Ridge, TN: U.S. Department of Energy. Accessed
September 13, 2005. http://cdiac.ornl.gov/trends/atm meth/lawdome meth.html.
Cape Grim, Australia: 1984 AD to 2013 AD
NOAA (National Oceanic and Atmospheric Administration). 2014. Monthly mean CH4 concentrations for
Cape Grim, Australia. Accessed April 8, 2014.
ftp://ftp.cmdl.noaa.gov/data/trace gases/ch4/flask/surface/ch4 ego surface-flask 1 ccgg month.txt.
Mauna Loa, Hawaii: 1987 AD to 2013 AD
NOAA (National Oceanic and Atmospheric Administration). 2014. Monthly mean CH4 concentrations for
Mauna Loa, Hawaii. Accessed April 8, 2014. ftp://ftp.cmdl.noaa.gov/data/trace gases/ch4/in-
situ/surface/mlo/ch4 mlo surface-insitu 1 ccgg month.txt.
Shetland Islands, Scotland: 1993 AD to 2001 AD
Steele, L.P., P.B. Krummel, and R.L. Langenfelds. 2002. Atmospheric methane record from Shetland
Islands, Scotland (October 2002 version). In: Trends: A compendium of data on global change. Oak
Ridge, TN: U.S. Department of Energy. Accessed September 13, 2005.
http://cdiac.esd.ornl.gov/trends/atm meth/csiro/csiro-shetlandch4.html.
Figure 3
EPICA Dome C, Antarctica: approximately 796,475 BC to 1937 AD
Schilt, A., M. Baumgartner, T. Blunier, J. Schwander, R. Spahni, H. Fischer, and T.F. Stocker. 2010. Glacial-
interglacial and millennial scale variations in the atmospheric nitrous oxide concentration during the last
800,000 years. Quaternary Sci. Rev. 29:182-192.
ftp://ftp.ncdc.noaa.gov/pub/data/paleo/icecore/antarctica/epica domec/edc-n2o-2010-800k.txt.
Antarctica: approximately 1903 AD to 1976 AD
Battle, M., M. Bender, T. Sowers, P. Tans, J. Butler, J. Elkins, J. Ellis, T. Conway, N. Zhang, P. Lang, and A.
Clarke. 1996. Atmospheric gas concentrations over the past century measured in air from firn at the
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d% Climate Change Indicators in the United States: Atmospheric Concentrations of
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South Pole. Nature 383:231-235.
ftp://daac.ornl.gov/data/global climate/global N cvcle/data/global N perturbations.txt.
Cape Grim, Australia: 1979 AD to 2012 AD
AGAGE (Advanced Global Atmospheric Gases Experiment). 2014. Monthly mean N20 concentrations for
Cape Grim, Australia. Accessed April 8, 2014. http://ds.data.ima.go.jp/gmd/wdcgg/cgi-
bin/wdcgg/catalogue.cgi.
South Pole, Antarctica: 1998 AD to 2013 AD
Barrow, Alaska: 1999 AD to 2013 AD
Mauna Loa, Hawaii: 2000 AD to 2013 AD
NOAA (National Oceanic and Atmospheric Administration). 2014. Monthly mean N20 concentrations for
Barrow, Alaska; Mauna Loa, Hawaii; and the South Pole. Accessed April 8, 2014.
www.esrl.noaa.gov/gmd/hats/insitu/cats/cats conc.html.
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