Estimating Stream Temperature from Air Temperature: Implications for Future Water Quality

This study examines the air temperature/stream temperature relationship at a geographically diverse set of streams. We evaluate the general temperature relationships (both linear and nonlinear) that apply to these streams, and then examine how changes in stream temperature associated with climate va...

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Bibliographic Details
Published inJournal of environmental engineering (New York, N.Y.) Vol. 131; no. 1; pp. 139 - 146
Main Authors Morrill, Jean C, Bales, Roger C, Conklin, Martha H
Format Journal Article
LanguageEnglish
Published Reston, VA American Society of Civil Engineers 01.01.2005
Subjects
Earth sciences
Earth, ocean, space
Exact sciences and technology
Freshwater
Hydrogeology
Hydrology. Hydrogeology
TECHNICAL PAPERS
surface water
air-water interface
temperature
water quality
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Abstract This study examines the air temperature/stream temperature relationship at a geographically diverse set of streams. We evaluate the general temperature relationships (both linear and nonlinear) that apply to these streams, and then examine how changes in stream temperature associated with climate variability or climate warming might affect dissolved oxygen levels. The majority of streams showed an increase in water temperature of about 0.6–0.8°C for every 1°C increase in air temperature, with very few streams displaying a linear 1:1 air/water temperature trend. For most of the streams, a nonlinear model produced a better fit than did a simple linear model. Understanding the relationship between air temperature and water temperature is important if people want to estimate how stream temperatures are likely to respond to anticipated future increases in surface air temperature. Surface water temperature in many streams will likely increase 2 to 3°C as air temperature increases 3 to 5°C. At sites with currently low dissolved oxygen content, an increase in summer stream temperatures could cause the dissolved oxygen levels to fall into a critically low range, threatening the health of many aquatic species.
AbstractList This study examines the air temperature/stream temperature relationship at a geographically diverse set of streams. We evaluate the general temperature relationships (both linear and nonlinear) that apply to these streams, and then examine how changes in stream temperature associated with climate variability or climate warming might affect dissolved oxygen levels. The majority of streams showed an increase in water temperature of about 0.6-0.8 degree C for every 1 degree C increase in air temperature, with very few streams displaying a linear 1:1 air/water temperature trend. For most of the streams, a nonlinear model produced a better fit than did a simple linear model. Understanding the relationship between air temperature and water temperature is important if people want to estimate how stream temperatures are likely to respond to anticipated future increases in surface air temperature. Surface water temperature in many streams will likely increase 2 to 3 degree C as air temperature increases 3 to 5 degree C. At sites with currently low dissolved oxygen content, an increase in summer stream temperatures could cause the dissolved oxygen levels to fall into a critically low range, threatening the health of many aquatic species.
This study examines the air temperature/stream temperature relationship at a geographically diverse set of streams. We evaluate the general temperature relationships (both linear and nonlinear) that apply to these streams, and then examine how changes in stream temperature associated with climate variability or climate warming might affect dissolved oxygen levels. The majority of streams showed an increase in water temperature of about 0.6-0.8DGC for every 1DGC increase in air temperature, with very few streams displaying a linear 1:1 air/water temperature trend. For most of the streams, a nonlinear model produced a better fit than did a simple linear model. Understanding the relationship between air temperature and water temperature is important if people want to estimate how stream temperatures are likely to respond to anticipated future increases in surface air temperature. Surface water temperature in many streams will likely increase 2 to 3DGC as air temperature increases 3 to 5DGC. At sites with currently low dissolved oxygen content, an increase in summer stream temperatures could cause the dissolved oxygen levels to fall into a critically low range, threatening the health of many aquatic species.
This study examines the air temperature/stream temperature relationship at a geographically diverse set of streams. We evaluate the general temperature relationships (both linear and nonlinear) that apply to these streams, and then examine how changes in stream temperature associated with climate variability or climate warming might affect dissolved oxygen levels. The majority of streams showed an increase in water temperature of about 0.6–0.8°C for every 1°C increase in air temperature, with very few streams displaying a linear 1:1 air/water temperature trend. For most of the streams, a nonlinear model produced a better fit than did a simple linear model. Understanding the relationship between air temperature and water temperature is important if people want to estimate how stream temperatures are likely to respond to anticipated future increases in surface air temperature. Surface water temperature in many streams will likely increase 2 to 3°C as air temperature increases 3 to 5°C. At sites with currently low dissolved oxygen content, an increase in summer stream temperatures could cause the dissolved oxygen levels to fall into a critically low range, threatening the health of many aquatic species.
Author Conklin, Martha H
Bales, Roger C
Morrill, Jean C
Author_xml – sequence: 1
  givenname: Jean C
  surname: Morrill
  fullname: Morrill, Jean C
  organization: Univ. of Arizona , , Dept. of Hydrology and Water Resouces, P.O. Box 210011, Tucson, AZ 85721-0011. E-mail
– sequence: 2
  givenname: Roger C
  surname: Bales
  fullname: Bales, Roger C
  email: rbales@ucmerced.edu
  organization: Univ. of California , , School of Engineering, P.O. Box 2039, Merced, CA 95344. E-mail
– sequence: 3
  givenname: Martha H
  surname: Conklin
  fullname: Conklin, Martha H
  email: mconklin@ucmerced.edu
  organization: Univ. of California , , School of Engineering, P.O. Box 2039, Merced, CA 95344. E-mail
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References Erickson, T. R.; Stefan, H. G. 2000; 5
Webb, B. W.; Nobilis, F. 1997; 11
Cooter, E. J.; Cooter, W. S. 1990; 1
Mohseni, O.; Erickson, T. R.; Stefan, H. G. 1999; 35
Stefan, H. G.; Preud’homme, E. B. 1993; 29
Stefan, H. G.; Fand, X.; Eaton, J. G. 2001; 130
Webb, B. W.; Walling, D. E. 1993; 7
Mohseni, O.; Stefan, H. G. 1999; 218
Webb, B. W.; Walling, D. E. 1992; 37
Webb, B. W. 1996; 10
Langan, S. J. 2001; 265
Pilgrim, J. M.; Fang, X.; Stefan, H. G. 1998; 34
Webb, B. W.; Nobilis, F. 1994; 291
Webb, B. W.; Nobilis, F. 1995; 40
Mohseni, O.; Erickson, T. R.; Stefan, H. G. 2002; 128
Mohseni, O.; Stefan, H. G.; Erickson, T. R. 1998; 34
Webb, B. W. 1987; 119
Intergovernmental Panel on Climate Change (e_1_3_1_6_1) 1999
Webb B. W. (e_1_3_1_17_1) 1987; 119
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References_xml – volume: 34
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Snippet This study examines the air temperature/stream temperature relationship at a geographically diverse set of streams. We evaluate the general temperature...
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SubjectTerms Earth sciences
Earth, ocean, space
Exact sciences and technology
Freshwater
Hydrogeology
Hydrology. Hydrogeology
TECHNICAL PAPERS
Title Estimating Stream Temperature from Air Temperature: Implications for Future Water Quality
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