The Past as Prelude to the Future for Understanding 21st‐Century Climate Effects on Rocky Mountain Trout

Isaak, Daniel J.; Muhlfeld, Clint C.; Todd, Andrew S.; Al‐Chokhachy, Robert; Roberts, James J.; Kershner, Jeffrey L.; Fausch, Kurt D.; Hostetler, Steven W.

doi:10.1080/03632415.2012.742808

Cited by 73 publications

(76 citation statements)

References 111 publications

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“…However, the intercatchment comparison among Star, Lynx, and Lyons East creeks demonstrates that T s patterns can differ under similar T a conditions, presenting a conceptual model for how thermal regimes may respond to hydroclimatic change in southwestern Alberta. Many studies suggest increases in future summer T s and thermal fragmentation in headwater streams during summer months (Isaak et al 2012b;Isaak and Rieman 2013;Jones et al 2013). While the approach used in this study likely produced conservative estimates of summer T s change, our results support Tague et al (2007).…”

Section: Discussionsupporting

confidence: 44%

“…Stream thermal regimes are likely to respond to changes in hydroclimatic regimes (Cristea and Burges 2010), as the capacity for streams to store heat is inversely proportional to volume (Poole and Berman 2001;Webb et al 2003). Degradation of thermal habitat as a result of anthropogenic and natural disturbance, coupled with competition from introduced species, will likely further reduce habitat availability for native salmonids in the Rocky Mountains (Meyer et al 1999;Isaak et al 2012a;Isaak et al 2012b;Jones et al 2013). Therefore, it is important to understand how hydrologic and thermal regimes of mountain streams will respond to climate change.…”

Section: Introductionmentioning

confidence: 98%

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Potential future climate effects on mountain hydrology, stream temperature, and native salmonid life history

MacDonaldRyan

BoonSarah

ByrneJames

et al. 2014

Can. J. Fish. Aquat. Sci.

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Native salmonids of western North America are subject to many environmental pressures, most notably the effects of introduced species and environmental degradation. To better understand how native salmonids on the eastern slopes of the Canadian Rocky Mountains may respond to future changes in climate, we applied a process-based approach to hydrologic and stream temperature modelling. This study demonstrates that stream thermal regimes in western Alberta, Canada, may only warm during the summer period, while colder thermal regimes during spring, fall, and winter could result from response to earlier onset of spring freshet. Model results of future climate impacts on hydrology and stream temperature are corroborated by an intercatchment comparison of stream temperature, air temperature, and hydrological conditions. Earlier fry emergence as a result of altered hydrological and thermal regimes may favour native westslope cutthroat trout (Oncorhynchus clarkii lewisii) in isolated headwater streams. Colder winter stream temperatures could result in longer incubation periods for native bull trout (Salvelinus confluentus) and limit threatened westslope cutthroat trout habitat.Résumé : Les salmonidés indigènes de l'ouest de l'Amérique du Nord sont assujettis à de nombreuses pressions ambiantes, notamment les effets d'espèces introduites et de la dégradation de l'environnement. Afin d'établir une meilleure compréhen-sion de la réaction possible des salmonidés indigènes sur le versant est de Rocheuses canadiennes aux changements climatiques futurs, nous avons appliqué une approche axée sur les processus à la modélisation de l'hydrologie et de la température des cours d'eau. L'étude démontre que les régimes thermiques des cours d'eau dans l'ouest de l'Alberta (Canada) pourraient ne se réchauffer que durant la période estivale, alors que des régimes thermiques plus froids au printemps, à l'automne et en hiver pourraient découler du devancement des crues printanières. Les résultats de la modélisation des impacts climatiques futurs sur l'hydrologie et la température des cours d'eau sont corroborés par la comparaison de la température des cours d'eau, de la température de l'air et des conditions hydrologiques dans différents bassins versants. L'émergence devancée des alevins décou-lant de la modification des régimes hydrologiques et thermiques pourrait favoriser la truite fardée versant (Oncorhynchus clarkii lewisii) dans des cours d'eau d'amont isolés. La diminution des températures hivernales des cours d'eau pourrait se traduire par de plus longues périodes d'incubation pour l'omble à tête plate (Salvelinus confluentus) indigène et limiter l'habitat de la truite fardée versant, une espèce menacée. [Traduit par la Rédaction]

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Section: Discussionsupporting

confidence: 44%

Section: Introductionmentioning

confidence: 98%

Potential future climate effects on mountain hydrology, stream temperature, and native salmonid life history

MacDonaldRyan

BoonSarah

ByrneJames

et al. 2014

Can. J. Fish. Aquat. Sci.

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“…It may be surprising that Bull Trout abundance has been stable or increasing across much of Idaho for the last several decades, considering that (1) climate change has been warming stream temperatures in portions of the Bull Trout's range in Idaho since at least 1980 (Isaak et al 2010 and (2) Bull Trout are expected to be among the fish species with the greatest sensitivity to climate change in western North America (Rieman et al 2007;Isaak et al 2010Isaak et al , 2012 due to their need for cold water temperatures and large patches of connected habitat (Rieman and McIntyre 1995;Dunham and Rieman 1999;Wenger et al 2011). While it likely that continued stream warming will at some point become measurably detrimental to Bull Trout, the disconnect between more than three decades of climate-induced stream warming and the positive trend in abundance for many Idaho Bull Trout populations over the same period is paradoxical.…”

Section: Trends In Abundancementioning

confidence: 98%

Bull Trout Trends in Abundance and Probabilities of Persistence in Idaho

Meyer

Garton

Schill

2014

N American J Fish Manag

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We estimated the population growth rates of Bull Trout Salvelinus confluentus and used population growth models to evaluate observation error and estimate Bull Trout persistence probabilities by using 25 data sets (averaging 19 years of record) that indexed abundance across Idaho. These data sets were derived from a variety of fish sampling techniques, including weirs, screw traps, redd counts, daytime snorkeling, electrofishing, and angler creel. Bull Trout populations in Idaho were relatively stable prior to 1994, but after 1994, substantially more population growth rates trended statistically upward (n = 14) than downward (n = 3). Average intrinsic rates of population change were 0.01 (SE = 0.03) prior to 1994 and 0.07 (SE = 0.02) after 1994; across all years of data, the rate of change averaged 0.07 (SE = 0.02). Fifty‐nine percent of the data sets had zero to minimal observation error according to Gompertz state‐space model estimates; observation error was least common in data from screw traps and redd counts and most common in snorkel data. Gompertz‐type density‐dependent models were most often the best‐fitting models for Bull Trout population growth. Moreover, few of the most reliable modeling results (i.e., those from data sets estimated to have zero to minimal observation error) contained a period effect or time (i.e., year) effect, suggesting that carrying capacity generally did not differ between the pre‐1994 and post‐1994 periods and generally was not trending positively or negatively through time. Parametric bootstraps predicted that the mean probability of falling below the quasi‐extinction level of 20 adults in the next 30 years was 9.8% (median = 4.7%) for data sets estimated to have zero to minimal observation error. The weight of evidence from our modeling results suggests that for most Bull Trout populations in Idaho, abundance is stable or increasing and the risk of extirpation in the foreseeable future is low.Received March 12, 2013; accepted November 18, 2013Published online February 10, 2014

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“…The ability to accurately project hydrologic conditions at the fine scale using macroscale models is limited (Wenger et al 2010). Therefore, short-term management priorities might include (1) biological monitoring to determine whether and how fast distributions are actually shifting, (2) development of better hydrologic estimates through additional empirical monitoring and finer-scale modeling, and (3) establishment of stream temperature monitoring sites (Isaak et al 2012). …”

Section: Discussionmentioning

confidence: 99%

Full Issue PDF Volume 38, Issue 3

2013

Fisheries

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There are numerous applications for CWTs. Examples are: evaluate how hatchery practices affect post release survival; identify the stock of origin and age; estimate population size; estimate fishery contributions of a particular stock over time; monitor habitat use; measure growth; evaluate whether stocked fish contribute to population recovery; learn about migration routes and straying between populations; evaluate the effects of climate change on Pacific salmon. Hundreds of publications describing their use are available on our website. Please contact us if we can help with your project. Corporate Office 360.468.3375 office@nmt.us Biological Services

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The Past as Prelude to the Future for Understanding 21st‐Century Climate Effects on Rocky Mountain Trout

Cited by 73 publications

References 111 publications

Potential future climate effects on mountain hydrology, stream temperature, and native salmonid life history

Potential future climate effects on mountain hydrology, stream temperature, and native salmonid life history

Bull Trout Trends in Abundance and Probabilities of Persistence in Idaho

Full Issue PDF Volume 38, Issue 3

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