AIMS Geosciences, 2018, 4(4): 192-214. doi: 10.3934/geosci.2018.4.192.

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Environmental factors controlling stream water temperature in a forest catchment

Laboratory of Physical Hydrology, Department of Earth and Planetary Sciences, Faculty of Science, Hokkaido University, Sapporo 060-0810, Japan

Heat budget of a stream, the Putoisaroma Stream, Hokkaido, Japan, in a forest catchment was estimated in order to investigate environmental factors controlling stream water temperature. In August 2008–October 2009, water temperature was measured at six sites along the stream channels, and the streambed temperature was measured at depths of 5 cm and 30 cm at one of the sites. In order to quantify incoming and outgoing radiations at the stream surface, hemispherical photographs were taken and the shading factors (ratio of the shade to the whole sky) were calculated at the observation sites over the summer. The shading factors, exhibiting seasonal and spatial variations, produced seasonal and spatial changes of shortwave and longwave radiations. The wind speed above stream surface was much smaller than in an open field, which produced turbulent heat fluxes one third as large as that in the open field. The shortwave and longwave radiations and the advective heat flux from upstream showed the major contribution to the stream heat budget, while the streambed heat conduction was secondary. The time series of stream water temperature were simulated well (RMSE = 0.771 ℃, NASH = 0.888) by applying the estimated heat budget. This evidences that the quantification of the shade above stream surface and the calculation of the heat budget are both reasonable. The sensitivity analysis for the simulation indicates that the shading factors along the stream channels control the stream water temperature.
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Keywords forest catchment; stream water temperature; shading factor; heat budget; groundwater; simulation

Citation: Kazuhisa A. Chikita. Environmental factors controlling stream water temperature in a forest catchment. AIMS Geosciences, 2018, 4(4): 192-214. doi: 10.3934/geosci.2018.4.192


  • 1. Webb BW, Hannah DM, Moore RD, et al. (2008) Recent advances in stream and river temperature research. Hydrol Proc 22: 902–918.    
  • 2. Webb BW, Zhang Y (1997) Spatial and seasonal variability in the components of the river heat budget. Hydrol Proc 11: 79–101.    
  • 3. Webb BW, Zhang Y (1999) Water temperatures and heat budgets in Dorset chalk water courses. Hydrol Proc 13: 309–321.    
  • 4. Moore RD, Sutherland P, Gomi T, et al. (2005) Thermal regime of a headwater stream within a clear-cut, coastal British Columbia, Canada. Hydrol Proc 19: 2591–2608.    
  • 5. Hannah DM, Malcolm IA, Soulsby C, et al. (2008) A comparison of forest and moorland stream microclimate, heat exchanges and thermal dynamics. Hydrol Proc 22: 919–940.    
  • 6. Benyahya L, Caissie D, El-Jabi N, et al. (2010) Comparison of microclimate vs. remote meteorological data and results applied to a water temperature model (Miramichi River, Canada). Jour Hydrol 380: 247–259.
  • 7. Nakamura F, Dokai T (1989) Estimation of the effect of riparian forest on stream temperature based on heat budget. Jour Jap Forestry Soc 71: 387–394.
  • 8. Sugimoto S, Nakamura F, Ito A (1997) Heat budget and statistical analysis of the relationship between stream temperature and riparian forest in the Toikanbetsu River basin, Northern Japan. Jour Forest Res 2: 103–107.    
  • 9. Dugdale SJ, Malcolm IA, Kantola K, et al. (2018) Stream temperature under contrasting riparian forest cover: Understanding thermal dynamics and heat exchange processes. Sci Total Environ 610–611: 1375–1389.
  • 10. Geological Survey of Hokkaido. (2004) The geology in Abashiri, Hokkaido, Japan. II The north and middle Abashiri (in Japanese).
  • 11. Baxter C, Hauer FR, Woessner WW (2003) Measuring groundwater-stream water exchange: new techniques for installing minipiezometers and estimating hydraulic conductivity. Trans Amer Fish Soc 132: 493–502.    
  • 12. Franzer GW, Canham CD, Lertzman KP (1999) Gap Light Analyzer (GLA), version 2.0: Imaging software to extract canopy structure and gap light transmission indices from true-colour fisheye photographs. User's Manual and Program Documentation. Simon Fraser University, Burnaby, B.C. and the Institute of Ecosystem Studies, Millbrook, NY.
  • 13. Kell GS (1975) Density, thermal expansivity, and compressibility of liquid water from 0 ℃ to 150 ℃: Correlations and tables for atmospheric pressure and saturation reviewed and expressed on 1968 temperature scale. Jour Chem Eng Data 20: 97–105.    
  • 14. Chikita KA, Kaminaga R, Kudo I, et al. (2009) Parameters determining water temperature of a glacial stream: The Phelan Creek and the Gulkana Glacier, Alaska. River Res Applic 26: 995–1004.
  • 15. McMahon A, Moore RD (2017) Influence of turbidity and aeration on the albedo of mountain streams. Hydrol Proc 31: 4477–4491.    
  • 16. Caissie D, Satish MG, El-Jabi N (2007) Predicting water temperatures using a deterministic model: Application on Miramichi River catchments (New Brunswick, Canada). Jour Hydrol 336: 303–315.    
  • 17. Morin G, Couillard D (1990) Predicting river temperatures with a hydrological model. Encyclopedia of Fluid Mechanic, Surface and Groundwater Flow Phenomena, 10, Houston, TX: Gulf Publishing Company, 171–209.
  • 18. Maidment DR (1992) Handbook of Hydrology. New York: McGraw-Hill.
  • 19. Theurer FD, Voos KA, Miller WJ (1984) Instream water temperature model. US Fish and Wildlife Service Instream Flow Information Paper 16, 200.
  • 20. Kondo J (1994) Meteorology in aquatic environments. Tokyo, Japan: Asakura Publishing Ltd., 350.


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