A century of temperature variability in Lake Superior

Austin, Jay A.; Colman, Steven M.

doi:10.4319/lo.2008.53.6.2724

Cited by 173 publications

(138 citation statements)

References 12 publications

(26 reference statements)

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“…Torbick et al [9] used satellite-derived data to study NENA lake skin temperatures from 1984 to 2014, finding that lake surface temperatures increased more rapidly than air temperatures during this period. These findings are consistent with other regional-and global-scale studies that reveal that lake surface temperatures are warming at a rate that is faster than expected given surrounding air temperature warming [10][11][12][13][14]. In addition to understanding surface water temperature trends, however, we need to determine if there is evidence of long-term changes in lake thermal structure and deepwater temperatures in the NENA region because these thermal habitats are critical to aquatic biota.…”

Section: Introductionsupporting

confidence: 67%

Transparency, Geomorphology and Mixing Regime Explain Variability in Trends in Lake Temperature and Stratification across Northeastern North America (1975–2014)

Richardson

Melles

Pilla

et al. 2017

Water

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Lake surface water temperatures are warming worldwide, raising concerns about the future integrity of valuable lake ecosystem services. In contrast to surface water temperatures, we know far less about what is happening to water temperature beneath the surface, where most organisms live. Moreover, we know little about which characteristics make lakes more or less sensitive to climate change and other environmental stressors. We examined changes in lake thermal structure for 231 lakes across northeastern North America (NENA), a region with an exceptionally high density of lakes. We determined how lake thermal structure has changed in recent decades and assessed which lake characteristics are related to changes in lake thermal structure. In general, NENA lakes had increasing near-surface temperatures and thermal stratification strength. On average, changes in deepwater temperatures for the 231 lakes were not significantly different than zero, but individually, half of the lakes experienced warming and half cooling deepwater temperature through time. More transparent lakes (Secchi transparency >5 m) tended to have higher near-surface warming and greater increases in strength of thermal stratification than less transparent lakes. Whole-lake warming was greatest in polymictic lakes, where frequent summer mixing distributed heat throughout the water column. Lakes often function as important sentinels of climate change, but lake characteristics within and across regions modify the magnitude of the signal with important implications for lake biology, ecology and chemistry.

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Section: Introductionsupporting

confidence: 67%

Transparency, Geomorphology and Mixing Regime Explain Variability in Trends in Lake Temperature and Stratification across Northeastern North America (1975–2014)

Richardson

Melles

Pilla

et al. 2017

Water

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“…Nitrogen cycling is of particular interest in Lake Superior because of the buildup of nitrate in the water column and an exceptionally high N : P ratio (Sterner et al 2007;Sterner 2011). That sediment OPD responds to the oxygen supply from the bottom waters suggests that sediment redox chemistry may be affected by the physical stratification of the water column, which is now being affected by climate warming (Austin and Colman 2008). Given the similarity to marine hemipelagic sediments (Fig.…”

Section: Discussionmentioning

confidence: 99%

Carbon mineralization and oxygen dynamics in sediments with deep oxygen penetration, Lake Superior

Crowe

Miklesh

et al. 2012

Limnology & Oceanography

108

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To understand carbon and oxygen dynamics in sediments with deep oxygen penetration, we investigated eight locations (160-318-m depth) throughout Lake Superior. Despite the 2-4 weight percent organic carbon content, oxygen penetrated into the sediment by 3.5 to . 12 cm at all locations. Such deep penetration is explained by low sedimentation rates (0.01-0.04 cm yr 21 ), high solubility of oxygen in freshwater, and a shallow (, 2 cm) bioturbation zone. In response mainly to oxygen variations in the bottom waters, the sediment oxygen penetration varied seasonally by as much as several centimeters, suggesting that temporal variability in deeply oxygenated sediments may be greater than previously acknowledged. The oxygen uptake rates (4.4-7.7 mmol m 22 d 21 , average 6.1 mmol m 22 d 21 ) and carbon mineralization efficiency (, 90% of deposited carbon) were similar to those in marine hemipelagic and pelagic sediments of comparable sedimentation rates. The reactivity of organic carbon was found to decrease with age similarly to the power-law documented in marine environments. The burial flux of carbon into the deep sediment (0.7 mmol m 22 d 21 ) was 2.5% of the previously estimated primary production. Maximum volume-specific carbon degradation rates were 0.3-1.5 mmol cm 23 d 21 ; bioturbation coefficient near the sediment surface was 3-8 cm 2 yr 21 . These results indicate that carbon cycling in large freshwater systems conforms to many of the same trends as in marine systems.

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“…Changing dynamics in lake/sea ice cover and its respective breakup and reformation dates can influence atmospheric conditions and stability. These changes can lead to varying wind speed over the Great Lakes and James Bay region, with a causal link existing between the observed decline in ice cover over the Great Lakes during the past decades, with an increasing wind speed during transition months (winter and fall) [24][25][26][27].…”

Section: Seasonal Wind Trends At Hub-heightmentioning

confidence: 99%

Feasibility of Small Wind Turbines in Ontario: Integrating Power Curves with Wind Trends

2016

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Micro-scale/small wind turbines, unlike larger utility-scale turbines, produce electricity at a rate of 300 W to 10 kW at their rated wind speed and are typically below 30 m in hub-height. These wind turbines have much more flexibility in their costs, maintenance and siting, owing to their size, and can provided wind energy in areas much less suited for direct supply to the grid system. In the future under climate change, the energy landscape will likely shift from the present centralized electricity generation and delivery system to a more distributed and locally-generated electricity and delivery system. In the new system configuration, the role of relatively small sustainable electricity generators like small wind turbines will likely become more prominent. However, the small wind industry has been substantially slow to progress in Ontario, Canada, and there is much debate over its viability in a growing energy dependent economy. This study seeks to demonstrate the performance of a small wind turbine, and speculate on its potential power output and trend over Ontario historically over the last 33 years using the North American Regional Reanalysis (NARR) data. We assessed the efficiency of a Bergey Excel 1 kW wind turbine at the pre-established Kortright Centre for Conservation test site, located north of Toronto. Using a novel approach, the Bergey optimized power curve was incorporated with reanalysis data to establish power output across Ontario at three-hour resolution. Small turbine-based wind power around the Great Lakes and eastern James Bay increased during winter and fall, contributing up to 10% of the annual electricity demand in some regions in Ontario. We purport that increases in power output are driven by long-term reductions in sea and lake ice concentrations affecting atmospheric stability in surrounding regions.

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A century of temperature variability in Lake Superior

Cited by 173 publications

References 12 publications

Transparency, Geomorphology and Mixing Regime Explain Variability in Trends in Lake Temperature and Stratification across Northeastern North America (1975–2014)

Transparency, Geomorphology and Mixing Regime Explain Variability in Trends in Lake Temperature and Stratification across Northeastern North America (1975–2014)

Carbon mineralization and oxygen dynamics in sediments with deep oxygen penetration, Lake Superior

Feasibility of Small Wind Turbines in Ontario: Integrating Power Curves with Wind Trends

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