Can brook trout survive climate change in large rivers? If it rains

We provide an assessment of thermal characteristics and climate change vulnerability for brook trout (Salvelinus fontinalis) habitats in the upper Shavers Fork sub-watershed, West Virginia. Spatial and temporal (2001–2015) variability in observed summer (6/1–8/31) stream temperatures was quantified...

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Bibliographic Details
Published in:The Science of the total environment 2017-12, Vol.607-608, p.1225-1236
Main Authors: Merriam, Eric R., Fernandez, Rodrigo, Petty, J. Todd, Zegre, Nicolas
Format: Article
Language:English
Subjects:
Salvelinus fontinalis
Stream networks
Stream temperature
Thermal habitat vulnerability
Thermal refugia
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Summary:We provide an assessment of thermal characteristics and climate change vulnerability for brook trout (Salvelinus fontinalis) habitats in the upper Shavers Fork sub-watershed, West Virginia. Spatial and temporal (2001–2015) variability in observed summer (6/1–8/31) stream temperatures was quantified in 23 (9 tributary, 14 main-stem) reaches. We developed a mixed effects model to predict site-specific mean daily stream temperature from air temperature and discharge and coupled this model with a hydrologic model to predict future (2016–2100) changes in stream temperature under low (RCP 4.5) and high (RCP 8.5) emissions scenarios. Observed mean daily stream temperature exceeded the 21°C brook trout physiological threshold in all but one main-stem site, and 3 sites exceeded proposed thermal limits for either 63- and 7-day mean stream temperature. We modeled mean daily stream temperature with a high degree of certainty (R2=0.93; RMSE=0.76°C). Predicted increases in mean daily stream temperature in main-stem and tributary reaches ranged from 0.2°C (RCP 4.5) to 1.2°C (RCP 8.5). Between 2091 and 2100, the average number of days with mean daily stream temperature>21°C increased within main-stem sites under the RCP 4.5 (0–1.2days) and 8.5 (0−13) scenarios; however, no site is expected to exceed 63- or 7-day thermal limits. During the warmest 10years, ≥5 main-stem sites exceeded the 63- or 7-day thermal tolerance limits under both climate emissions scenarios. Years with the greatest increases in stream temperature were characterized by low mean daily discharge. Main-stem reaches below major tributaries never exceed thermal limits, despite neighboring reaches having among the highest observed and predicted stream temperatures. Persistence of thermal refugia within upper Shavers Fork would enable persistence of metapopulation structure and life history processes. However, this will only be possible if projected increases in discharge are realized and offset expected increases in air temperature. [Display omitted] •Brook trout habitat vulnerability was assessed within an Appalachian watershed.•Increased discharge largely offset effects of increased air temperature.•No consistent loss of suitable brook trout habitat by end of 21st century•However, periods of low flow resulted in a loss of habitat at the network-scale.•Persistence of refugia below tributaries should enable metapopulation persistence.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2017.07.049