Regional and hierarchical perspectives of thermal regimes in subarctic, Alaskan lakes

Edmundson, J. A.; Mazumder, Asit

doi:10.1046/j.1365-2427.2002.00775.x

Cited by 39 publications

(41 citation statements)

References 42 publications

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“…Recently, many studies have revealed a marked increment in the heat content, ABHB, and water temperature of natural lakes (MORTSCH and QUINN, 1996;STEFFAN et al, 1998;AMBROSETTI and BARBANTI, 1999;AMBROSETTI and BARBANTI, 2001;BLENCKNER, 2005), and have also stressed the importance of these calculations to our understanding of potential response of aquatic ecosystems to climate change (EDMUNSON and MAZUMDER, 2002). Interestingly, our results demonstrated that the hydraulic management applied to Sau Reservoir induced a progressive temporal reduction on the average temperature and heat content in the reservoir, thus counteracting the generalized warming trend.…”

Section: Discussionsupporting

confidence: 56%

Hydraulic Management Drives Heat Budgets and Temperature Trends in a Mediterranean Reservoir

Moreno-Ostos

Marcé

Ordóñez

et al. 2008

International Review of Hydrobiology

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By contrast to the more regular and predictable temperate lakes, heat budgets and temperature dynamics in Mediterranean reservoirs are characterized by a marked interannual variability. In the present paper, the heat content, annual Birgean heat budget (ABHB), and thermal structure of Sau Reservoir were examined during a period of hypolimnetic withdrawal between 1980 and 1985, and during a period of withdrawal at intermediate depths between 1996 and 2003. The two study periods were also characterized by a wide range of stored water volume fluctuations. Results were used to develop and validate an empirical model to predict annual and monthly heat dynamics statistics and mixed layer depth as a function of hydraulic management parameters such as water volume and selective withdrawal depth. During the hypolimnetic withdrawal period elevated ABHB and deep mixed layer depths were recorded in the reservoir, which behaved as a heat trap. By contrast, intermediate depth withdrawal promoted a shallower and more stable thermocline, thus increasing the cold hypolimnetic water volume and decreasing heat content and ABHB. The study reveals that hydraulic management constitutes the main driver of the heat and thermal dynamics in reservoirs with multiple withdrawal outlets. By contrast with the increasing temperature trends recorded in many natural lakes, the hydraulic management in Sau Reservoir induced a progressive reduction in water temperature and heat content in the system, thus partially counteracting the possible deleterious effects of global warming. Our intensive study in a single, highly-dynamic ecosystem constitutes a new approximation to the study of thermal structure and heat dynamics in water bodies.

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Section: Discussionsupporting

confidence: 56%

Hydraulic Management Drives Heat Budgets and Temperature Trends in a Mediterranean Reservoir

Moreno-Ostos

Marcé

Ordóñez

et al. 2008

International Review of Hydrobiology

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“…Since the pioneering work of Birge (1916), many studies have analyzed heat fluxes from lakes from around the world, including temperate lakes (Hutchinson and Edmondson, 1957), tropical lakes (Lewis, 1973), and subarctic lakes (Edmundson and Mazumder, 2002).…”

Section: Discussionmentioning

confidence: 99%

Automated calculation of surface energy fluxes with high-frequency lake buoy data

Woolway

Jones

Hamilton

et al. 2015

Environmental Modelling & Software

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Lake Heat Flux Analyzer is a program used for calculating the surface energy fluxes in lakes according to established literature methodologies. The program was developed in MATLAB for the rapid analysis of high-frequency data from instrumented lake buoys in support of the emerging field of aquatic sensor network science. To calculate the surface energy fluxes, the program requires a number of input variables, such as air and water temperature, relative humidity, wind speed, and short-wave radiation. Available outputs for Lake Heat Flux Analyzer include the surface fluxes of momentum, sensible heat and latent heat and their corresponding transfer coefficients, incoming and outgoing long-wave radiation. Lake HeatFlux Analyzer is open source and can be used to process data from multiple lakes rapidly. It provides a means of calculating the surface fluxes using a consistent method, thereby facilitating global comparisons of high-frequency data from lake buoys.3

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“…In contrast, surface-water temperature models reported in the literature typically incorporated lake morphology (e.g. Shuter et al, 1983;Shuter & Post, 1990;Snucins & Gunn, 2000;Edmundson & Mazumder, 2002;Kettle et al, 2004) and water chemistry variables, such as turbidity (e.g. Snucins & Gunn, 2000;Edmundson & Mazumder, 2002).…”

Section: Discussionmentioning

confidence: 99%

Will northern fish populations be in hot water because of climate change?

Sharma

Jackson

Minns

et al. 2007

Global Change Biology

209

220

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Predicted increases in water temperature in response to climate change will have large implications for aquatic ecosystems, such as altering thermal habitat and potential range expansion of fish species. Warmwater fish species, such as smallmouth bass, Micropterus dolomieu, may have access to additional favourable thermal habitat under increased surface-water temperatures, thereby shifting the northern limit of the distribution of the species further north in Canada and potentially negatively impacting native fish communities. We assembled a database of summer surface-water temperatures for over 13 000 lakes across Canada. The database consists of lakes with a variety of physical, chemical and biological properties. We used general linear models to develop a nationwide maximum lake surface-water temperature model. The model was extended to predict surface-water temperatures suitable to smallmouth bass and under climatechange scenarios. Air temperature, latitude, longitude and sampling time were good predictors of present-day maximum surface-water temperature. We predicted lake surface-water temperatures for July 2100 using three climate-change scenarios. Water temperatures were predicted to increase by as much as 18 1C by 2100, with the greatest increase in northern Canada. Lakes with maximum surface-water temperatures suitable for smallmouth bass populations were spatially identified. Under several climate-change scenarios, we were able to identify lakes that will contain suitable thermal habitat and, therefore, are vulnerable to invasion by smallmouth bass in 2100. This included lakes in the Arctic that were predicted to have suitable thermal habitat by 2100.

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Regional and hierarchical perspectives of thermal regimes in subarctic, Alaskan lakes

Cited by 39 publications

References 42 publications

Hydraulic Management Drives Heat Budgets and Temperature Trends in a Mediterranean Reservoir

Hydraulic Management Drives Heat Budgets and Temperature Trends in a Mediterranean Reservoir

Automated calculation of surface energy fluxes with high-frequency lake buoy data

Will northern fish populations be in hot water because of climate change?

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