Climate Change Indicators in the United States: Heavy Precipitation
www.epa.gov/climatechange/indicators - Updated June 2015
Heavy Precipitation
This indicator tracks the frequency of heavy precipitation events in the United States.
Background
"Heavy precipitation" refers to instances during which the amount of rain or snow experienced in a
location substantially exceeds what is normal. What constitutes a period of heavy precipitation varies
according to location and season.
Climate change can affect the intensity and frequency of precipitation. Warmer oceans increase the
amount of water that evaporates into the air. When more moisture-laden air moves over land or
converges into a storm system, it can produce more intense precipitation—for example, heavier rain
and snow storms.1 The potential impacts of heavy precipitation include crop damage, soil erosion, and
an increase in flood risk due to heavy rains. In addition, runoff from precipitation can impair water
quality as pollutants deposited on land wash into water bodies.
Heavy precipitation does not necessarily mean the total amount of precipitation at a location has
increased—just that precipitation is occurring in more intense events. However, changes in the intensity
of precipitation, when combined with changes in the interval between precipitation events, can also
lead to changes in overall precipitation totals.
About the Indicator
Heavy precipitation events can be measured by tracking their frequency, examining their return period
(the chance that the event will be equaled or exceeded in a given year), or directly measuring the
amount of precipitation in a certain period (for example, inches of rain falling in a 24-hour period).
One way to track heavy precipitation is by calculating what percentage of a particular location's total
precipitation in a given year has come in the form of extreme one-day events—or, in other words, what
percentage of precipitation is arriving in short, intense bursts. Figure 1 of this indicator looks at the
prevalence of extreme single-day precipitation events over time.
For added insight, this indicator also tracks the occurrence of unusually high total yearly precipitation. It
does so by looking at the Standardized Precipitation Index (SPI), which compares actual yearly
precipitation totals with the range of precipitation totals that one would typically expect at a specific
location, based on historical data. If a location experiences less precipitation than normal during a
particular period, it will receive a negative SPI score, while a period with more precipitation than normal
will receive a positive score. The more precipitation (compared with normal), the higher the SPI score.
The SPI is a useful way to look at precipitation totals because it allows comparison of different locations
and different seasons on a standard scale. Figure 2 shows what percentage of the total area of the
contiguous 48 states had an annual SPI score of 2.0 or above (well above normal) in any given year.
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Climate Change Indicators in the United States: Heavy Precipitation
www.epa.gov/climatechange/indicators - Updated June 2015
Key Points
In recent years, a larger percentage of precipitation has come in the form of intense single-day
events. Eight of the top 10 years for extreme one-day precipitation events have occurred since
1990 (see Figure 1).
The prevalence of extreme single-day precipitation events remained fairly steady between 1910
and the 1980s, but has risen substantially since then. Over the entire period from 1910 to 2014,
the portion of the country experiencing extreme single-day precipitation events increased at a
rate of about half a percentage point per decade (see Figure 1).
The percentage of land area experiencing much greater than normal yearly precipitation totals
increased between 1895 and 2014. However, there has been much year-to-year variability. In
some years there were no abnormally wet areas, while a few others had abnormally high
precipitation totals over 10 percent or more of the contiguous 48 states' land area (see Figure
2). For example, 1941 was extremely wet in the West, while 1982 was very wet nationwide.2
Figures 1 and 2 are both consistent with other studies that have found an increase in heavy
precipitation over timeframes ranging from single days to 90-day periods to whole years.3 For
more information on trends in overall precipitation levels, see the U.S. and Global Precipitation
indicator.
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Climate Change Indicators in the United States: Heavy Precipitation
www.epa.gov/climatechange/indicators - Updated June 2015
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Figure 1. Extreme One-Day Precipitation Events in the Contiguous
48 States, 1910-2014
25
Percent of land area
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1910
1920 1930 1940 1950 1960 1970 1980 1990 2000 2010 2020
Year
This figure shows the percentage of the land area of the contiguous 48 states where a much greater than
normal portion of total annual precipitation has come from extreme single-day precipitation events. The
bars represent individual years, while the line is a nine-year weighted average.
Data source: NOAA, 20154
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Climate Change Indicators in the United States: Heavy Precipitation
www.epa.gov/clirnatechange/indicators - Updated June 2015
Figure 2. Unusually High Annual Precipitation in the Contiguous
48 States, 1895-2014
This figure shows the percentage of the land area of the contiguous 48 states that experienced much
greater than normal precipitation in any given year, which means it scored 2.0 or above on the annual
Standardized Precipitation Index. The thicker line shows a nine-year weighted average that smoothes out
some of the year-to-year fluctuations.
Data source: NQAA, 2015s
Indicator Notes
Weather monitoring stations tend to be closer together in the eastern and central states than in the
western states. In areas with fewer monitoring stations, heavy precipitation indicators are less likely to
reflect local conditions accurately.
Data Sources
The data used for this indicator come from a large national network of weather stations and were
provided by the National Oceanic and Atmospheric Administration's (NOAA's) National Centers for
Environmental Information. Figure 1 is based on Step #4 of NOAA's U.S. Climate Extremes Index; for
data and a description of the index, see: www.ncdc.noaa.gov/extremes/cei. Figure 2 is based on the U.S.
SPI, which is shown in a variety of maps available online at: www.ncdc.noaa.gov/sotc/drought. The data
used to construct these maps are available at: ftp://ftp.ncdc.noaa.gov/pub/data/cirs/climdiv/.
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Climate Change Indicators in the United States: Heavy Precipitation
www.epa.gov/climatechange/indicators - Updated June 2015
1 Melillo, J.M., T.C. Richmond, and G.W. Yohe (eds.). 2014. Climate change impacts in the United States: The third
National Climate Assessment. U.S. Global Change Research Program, http://nca2014.globalchange.gov.
2 NOAA (National Oceanic and Atmospheric Administration). 2012. National Climatic Data Center. Personal
communication: Analysis by Derek Arndt, April 2012.
3 CCSP (U.S. Climate Change Science Program). 2008. Synthesis and Assessment Product 3.3: Weather and climate
extremes in a changing climate, www.globalchange.gov/browse/reports/sap-33-weather-and-climate-extremes-
changing-climate.
4 NOAA (National Oceanic and Atmospheric Administration). 2015. U.S. Climate Extremes Index. Accessed March
2015. www.ncdc.noaa.gov/extremes/cei.
5 NOAA (National Oceanic and Atmospheric Administration). 2015. Standardized Precipitation Index data files.
Accessed March 2015. ftp://ftp.ncdc.noaa.gov/pub/data/cirs/climdiv/.
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