Climate Change Indicators in the United States Stream Temperature

Climate Change Indicators in the United States: Stream Temperature
www.epa.gov/climate-indicators - August 2016

Stream Temperature

This indicator shows changes in stream water temperature across the Chesapeake Bay region.
Background

Water temperature is an important physical property of every river and stream. Many plants, animals,
and other organisms living in streams can flourish only in a specific range of water temperatures.
Temperature can affect certain aspects of water quality. For example, higher temperatures reduce levels
of dissolved oxygen in the water, which can negatively affect the growth and productivity of aquatic life.
Persistently warmer temperatures in streams can accelerate natural chemical reactions and release
excess nutrients into the water.1 A stream's water temperature can also influence the circulation or
mixing patterns in the water it flows into, like bays and estuaries, potentially affecting nutrient levels
and salinity.

Temperatures can vary naturally along the length of a stream, from cold temperatures near a source of
meltwater to higher temperatures near its outlet to the sea. The temperature at any given point is a
product of many different factors, including sources of water (for example, melted snow, a recent
rainstorm, or groundwater), the amount of water in the stream (streamflow), air temperature, plants
along the bank (for example, trees that provide shade), and the amount of development within the
watershed. Over time, however, an area's climate has the strongest natural influence on a stream's
temperature.

The Chesapeake Bay is the largest estuary in the United States, an important habitat for countless
aquatic species, and a driver of the regional economy. As rising air temperatures (see the U.S. and
Global Temperature indicator) cause stream temperatures to rise, warmer stream water coming into the
bay can stress plants and animals and worsen the effects of nutrient pollution that the bay is already
facing.2

About the Indicator

The U.S. Geological Survey maintains thousands of stream gauges across the United States. Each gauge
measures water levels several times a day, typically every 15 minutes. Field technicians visit each
gauging station an average of eight times a year to measure various stream conditions, including water
temperature. This indicator shows how average water temperatures throughout the year changed
between 1960 and 2014 at 129 stream gauges located across the Chesapeake Bay region. These stations
were selected because they had high-quality data for this entire time period.

• From 1960 through 2014, water temperature increased at 79 percent of the stream sites

measured in the Chesapeake Bay region (see Figure 1). More than half of these increases were

Key Points

-------
Climate Change Indicators in the United States: Stream Temperature
www.epa.gov/climate-indicators - August 2016

statistically significant. Only 5 percent of stations had a significant temperature decrease over
the same period.

•	Since 1960, the Chesapeake Bay region has experienced an overall increase in stream water
temperature. Temperature has risen by an average of 1.2°F across all sites and 2.2°F at the sites
where trends were statistically significant.

•	Stream temperatures have risen throughout the Chesapeake Bay region. The largest increases
have occurred in the southern part of the region.

oEPA

2

-------
Climate Change Indicators in the United States: Stream Temperature

www.epa.gov/climate-indicators - August 2016

Figure 1. Changes in Stream Water Temperatures in the Chesapeake Bay Region, 1960-2014

~

%

New York

ft.

O	° ° o

o

o 0 ° °o °

OO	o o



t

O 1 O

»oO

o

Pennsylvania

0#

®0	a	#	A New Jersey

c ^ O •	oC*

•	#0°

o%°

Ohio	o a ®	Maryland ° 9° o

™ o	A

o

^Delaware

DC

Chesapeake Bay Watershed

• •

West Virginia

\a A	Chesapeake

Virginia	Bay

North Carolina

Total change (°F):

• • • #

> -4 -4 to -2 -2 to -1 -1 to 1 1 to 2 2 to 4	>4

Filled shapes represent statistically significant trends.

Open shapes represent trends that are not statistically significant.

This map shows the change in water temperature at 129 stream gauges across the Chesapeake Bay
region from 1960 to 2014. Red circles show locations where temperatures have increased; blue circles
show locations where temperatures have decreased. Filled circles represent sites where the change was
statistically significant.

Data source: Jastram and Rice, 20153

3

-------
Climate Change Indicators in the United States: Stream Temperature
www.epa.gov/climate-indicators - August 2016

Indicator Notes

In addition to climate, changes to a stream's average water temperature can be influenced by other
factors such as industrial discharges, changes to local hydrology (such as construction and operation of
dams and channels), and changes to land cover in the watershed. This indicator uses measurements
from all stream gauges with sufficient data. Thus, it includes some stream sites that are likely more
disturbed by human activities than others. A more detailed analysis of this data set found that water
temperature tends to increase more quickly than air temperature in agricultural areas without major
dams, but more slowly at forested sites and in areas influenced by dams.4 Nonetheless, a comparison of
35 relatively undisturbed reference stations with the remaining 94 stations in this indicator showed no
significant difference in trends between the two groups of stations.5

This indicator is based on measurements that are collected an average of eight times per year, but more
in some years and less in others. The data were analyzed in a way that accounts for variations in timing
and makes it possible to compare average temperatures across many years.

Data Sources

This indicator is based on an analysis developed by the U.S. Geological Survey (USGS).6 Periodic
temperature data were collected by the USGS, and these data are stored in the USGS National Water
Information System.

1 Duan, S.W., and S.S. Kaushal. 2013. Warming increases carbon and nutrient fluxes from sediments in streams
across land use. Biogeosciences 10:1193-1207.

2 Duan, S.W., and S.S. Kaushal. 2013. Warming increases carbon and nutrient fluxes from sediments in streams
across land use. Biogeosciences 10:1193-1207.

3 Jastram, J.D., and K.C. Rice. 2015. Air- and stream-water-temperature trends in the Chesapeake Bay region,
1960-2014. U.S. Geological Survey Open-File Report 2015-1207.
https://pubs.er.usgs.gov/publication/ofr20151207.

4 Rice, K.C., and J.D. Jastram. 2015. Rising air and stream-water temperatures in Chesapeake Bay region, USA.
Climatic Change 128(1):127-138.

5 Jastram, J.D., and K.C. Rice. 2015. Air- and stream-water-temperature trends in the Chesapeake Bay region,
1960-2014. U.S. Geological Survey Open-File Report 2015-1207.
https://pubs.er.usgs.gov/publication/ofr20151207.

6 Rice, K.C., and J.D. Jastram. 2015. Rising air and stream-water temperatures in Chesapeake Bay region, USA.
Climatic Change 128(1):127-138.

oEPA

-------