POTENTIAL EFFECTS OF CLIMATE CHANGES ON AQUATIC SYSTEMS: LAURENTIAN GREAT LAKES AND PRECAMBRIAN SHIELD REGION

The region studied includes the Laurentian Great Lakes and a diversity of smaller glacial lakes, streams and wetlands south of permanent permafrost and towards the southern extent of Wisconsin glaciation. We emphasize lakes and quantitative implications. The region is warmer and wetter than it has b...

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Published in:Hydrological processes 1997-06, Vol.11 (8), p.825-871
Main Authors: MAGNUSON, J. J., WEBSTER, K. E., ASSEL, R. A., BOWSER, C. J., DILLON, P. J., EATON, J. G., EVANS, H. E., FEE, E. J., HALL, R. I., MORTSCH, L. R., SCHINDLER, D. W., QUINN, F. H.
Format: Article
Language:English
Subjects:
aquatic systems
biogeochemistry
chemical limnology
climate change
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Exact sciences and technology
fish
Freshwater
heterogeneity in response
Hydrology
Hydrology. Hydrogeology
interaction with other stresses
lake ice
Laurentian Great Lakes
north temperate glacial lakes
paleoclimates
physical limnology
phytoplankton
Pollution, environment geology
Precambrian Shield
terrestrial-aquatic linkages
water level
zooplankton
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container_end_page 871
container_issue 8
container_start_page 825
container_title Hydrological processes
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creator MAGNUSON, J. J.
WEBSTER, K. E.
ASSEL, R. A.
BOWSER, C. J.
DILLON, P. J.
EATON, J. G.
EVANS, H. E.
FEE, E. J.
HALL, R. I.
MORTSCH, L. R.
SCHINDLER, D. W.
QUINN, F. H.
description The region studied includes the Laurentian Great Lakes and a diversity of smaller glacial lakes, streams and wetlands south of permanent permafrost and towards the southern extent of Wisconsin glaciation. We emphasize lakes and quantitative implications. The region is warmer and wetter than it has been over most of the last 12000 years. Since 1911 observed air temperatures have increased by about 0·11°C per decade in spring and 0·06°C in winter; annual precipitation has increased by about 2·1% per decade. Ice thaw phenologies since the 1850s indicate a late winter warming of about 2·5°C. In future scenarios for a doubled CO2 climate, air temperature increases in summer and winter and precipitation decreases (summer) in western Ontario but increases (winter) in western Ontario, northern Minnesota, Wisconsin and Michigan. Such changes in climate have altered and would further alter hydrological and other physical features of lakes. Warmer climates, i.e. 2 × CO2 climates, would lower net basin water supplies, stream flows and water levels owing to increased evaporation in excess of precipitation. Water levels have been responsive to drought and future scenarios for the Great Lakes simulate levels 0·2 to 2·5 m lower. Human adaptation to such changes is expensive. Warmer climates would decrease the spatial extent of ice cover on the Great Lakes; small lakes, especially to the south, would no longer freeze over every year. Temperature simulations for stratified lakes are 1–7°C warmer for surface waters, and 6°C cooler to 8°C warmer for deep waters. Thermocline depth would change (4 m shallower to 3·5 m deeper) with warmer climates alone; deepening owing to increases in light penetration would occur with reduced input of dissolved organic carbon (DOC) from dryer catchments. Dissolved oxygen would decrease below the thermocline. These physical changes would in turn affect the phytoplankton, zooplankton, benthos and fishes. Annual phytoplankton production may increase but many complex reactions of the phytoplankton community to altered temperatures, thermocline depths, light penetrations and nutrient inputs would be expected. Zooplankton biomass would increase, but, again, many complex interactions are expected. Generally, the thermal habitat for warm‐, cool‐ and even cold‐water fishes would increase in size in deep stratified lakes, but would decrease in shallow unstratified lakes and in streams. Less dissolved oxygen below the thermocline of lakes would further d
doi_str_mv 10.1002/(SICI)1099-1085(19970630)11:8<825::AID-HYP509>3.0.CO;2-G
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J. ; WEBSTER, K. E. ; ASSEL, R. A. ; BOWSER, C. J. ; DILLON, P. J. ; EATON, J. G. ; EVANS, H. E. ; FEE, E. J. ; HALL, R. I. ; MORTSCH, L. R. ; SCHINDLER, D. W. ; QUINN, F. H.</creator><contributor>Cushing, CE</contributor><creatorcontrib>MAGNUSON, J. J. ; WEBSTER, K. E. ; ASSEL, R. A. ; BOWSER, C. J. ; DILLON, P. J. ; EATON, J. G. ; EVANS, H. E. ; FEE, E. J. ; HALL, R. I. ; MORTSCH, L. R. ; SCHINDLER, D. W. ; QUINN, F. H. ; Cushing, CE</creatorcontrib><description>The region studied includes the Laurentian Great Lakes and a diversity of smaller glacial lakes, streams and wetlands south of permanent permafrost and towards the southern extent of Wisconsin glaciation. We emphasize lakes and quantitative implications. The region is warmer and wetter than it has been over most of the last 12000 years. Since 1911 observed air temperatures have increased by about 0·11°C per decade in spring and 0·06°C in winter; annual precipitation has increased by about 2·1% per decade. Ice thaw phenologies since the 1850s indicate a late winter warming of about 2·5°C. In future scenarios for a doubled CO2 climate, air temperature increases in summer and winter and precipitation decreases (summer) in western Ontario but increases (winter) in western Ontario, northern Minnesota, Wisconsin and Michigan. Such changes in climate have altered and would further alter hydrological and other physical features of lakes. Warmer climates, i.e. 2 × CO2 climates, would lower net basin water supplies, stream flows and water levels owing to increased evaporation in excess of precipitation. Water levels have been responsive to drought and future scenarios for the Great Lakes simulate levels 0·2 to 2·5 m lower. Human adaptation to such changes is expensive. Warmer climates would decrease the spatial extent of ice cover on the Great Lakes; small lakes, especially to the south, would no longer freeze over every year. Temperature simulations for stratified lakes are 1–7°C warmer for surface waters, and 6°C cooler to 8°C warmer for deep waters. Thermocline depth would change (4 m shallower to 3·5 m deeper) with warmer climates alone; deepening owing to increases in light penetration would occur with reduced input of dissolved organic carbon (DOC) from dryer catchments. Dissolved oxygen would decrease below the thermocline. These physical changes would in turn affect the phytoplankton, zooplankton, benthos and fishes. Annual phytoplankton production may increase but many complex reactions of the phytoplankton community to altered temperatures, thermocline depths, light penetrations and nutrient inputs would be expected. Zooplankton biomass would increase, but, again, many complex interactions are expected. Generally, the thermal habitat for warm‐, cool‐ and even cold‐water fishes would increase in size in deep stratified lakes, but would decrease in shallow unstratified lakes and in streams. Less dissolved oxygen below the thermocline of lakes would further degrade stratified lakes for cold water fishes. Growth and production would increase for fishes that are now in thermal environments cooler than their optimum but decrease for those that are at or above their optimum, provided they cannot move to a deeper or headwater thermal refuge. The zoogeographical boundary for fish species could move north by 500–600 km; invasions of warmer water fishes and extirpations of colder water fishes should increase. Aquatic ecosystems across the region do not necessarily exhibit coherent responses to climate changes and variability, even if they are in close proximity. Lakes, wetlands and streams respond differently, as do lakes of different depth or productivity. Differences in hydrology and the position in the hydrological flow system, in terrestrial vegetation and land use, in base climates and in the aquatic biota can all cause different responses. Climate change effects interact strongly with effects of other human‐caused stresses such as eutrophication, acid precipitation, toxic chemicals and the spread of exotic organisms. Aquatic ecological systems in the region are sensitive to climate change and variation. Assessments of these potential effects are in an early stage and contain many uncertainties in the models and properties of aquatic ecological systems and of the climate system. © 1997 John Wiley &amp; Sons, Ltd.</description><identifier>ISSN: 0885-6087</identifier><identifier>EISSN: 1099-1085</identifier><identifier>DOI: 10.1002/(SICI)1099-1085(19970630)11:8&lt;825::AID-HYP509&gt;3.0.CO;2-G</identifier><identifier>CODEN: HYPRE3</identifier><language>eng</language><publisher>West Sussex: John Wiley &amp; Sons, Ltd</publisher><subject>aquatic systems ; biogeochemistry ; chemical limnology ; climate change ; Earth sciences ; Earth, ocean, space ; Engineering and environment geology. 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J.</creatorcontrib><creatorcontrib>WEBSTER, K. E.</creatorcontrib><creatorcontrib>ASSEL, R. A.</creatorcontrib><creatorcontrib>BOWSER, C. J.</creatorcontrib><creatorcontrib>DILLON, P. J.</creatorcontrib><creatorcontrib>EATON, J. G.</creatorcontrib><creatorcontrib>EVANS, H. E.</creatorcontrib><creatorcontrib>FEE, E. J.</creatorcontrib><creatorcontrib>HALL, R. I.</creatorcontrib><creatorcontrib>MORTSCH, L. R.</creatorcontrib><creatorcontrib>SCHINDLER, D. W.</creatorcontrib><creatorcontrib>QUINN, F. H.</creatorcontrib><title>POTENTIAL EFFECTS OF CLIMATE CHANGES ON AQUATIC SYSTEMS: LAURENTIAN GREAT LAKES AND PRECAMBRIAN SHIELD REGION</title><title>Hydrological processes</title><addtitle>Hydrol. Process</addtitle><description>The region studied includes the Laurentian Great Lakes and a diversity of smaller glacial lakes, streams and wetlands south of permanent permafrost and towards the southern extent of Wisconsin glaciation. We emphasize lakes and quantitative implications. The region is warmer and wetter than it has been over most of the last 12000 years. Since 1911 observed air temperatures have increased by about 0·11°C per decade in spring and 0·06°C in winter; annual precipitation has increased by about 2·1% per decade. Ice thaw phenologies since the 1850s indicate a late winter warming of about 2·5°C. In future scenarios for a doubled CO2 climate, air temperature increases in summer and winter and precipitation decreases (summer) in western Ontario but increases (winter) in western Ontario, northern Minnesota, Wisconsin and Michigan. Such changes in climate have altered and would further alter hydrological and other physical features of lakes. Warmer climates, i.e. 2 × CO2 climates, would lower net basin water supplies, stream flows and water levels owing to increased evaporation in excess of precipitation. Water levels have been responsive to drought and future scenarios for the Great Lakes simulate levels 0·2 to 2·5 m lower. Human adaptation to such changes is expensive. Warmer climates would decrease the spatial extent of ice cover on the Great Lakes; small lakes, especially to the south, would no longer freeze over every year. Temperature simulations for stratified lakes are 1–7°C warmer for surface waters, and 6°C cooler to 8°C warmer for deep waters. Thermocline depth would change (4 m shallower to 3·5 m deeper) with warmer climates alone; deepening owing to increases in light penetration would occur with reduced input of dissolved organic carbon (DOC) from dryer catchments. Dissolved oxygen would decrease below the thermocline. These physical changes would in turn affect the phytoplankton, zooplankton, benthos and fishes. Annual phytoplankton production may increase but many complex reactions of the phytoplankton community to altered temperatures, thermocline depths, light penetrations and nutrient inputs would be expected. Zooplankton biomass would increase, but, again, many complex interactions are expected. Generally, the thermal habitat for warm‐, cool‐ and even cold‐water fishes would increase in size in deep stratified lakes, but would decrease in shallow unstratified lakes and in streams. Less dissolved oxygen below the thermocline of lakes would further degrade stratified lakes for cold water fishes. Growth and production would increase for fishes that are now in thermal environments cooler than their optimum but decrease for those that are at or above their optimum, provided they cannot move to a deeper or headwater thermal refuge. The zoogeographical boundary for fish species could move north by 500–600 km; invasions of warmer water fishes and extirpations of colder water fishes should increase. Aquatic ecosystems across the region do not necessarily exhibit coherent responses to climate changes and variability, even if they are in close proximity. Lakes, wetlands and streams respond differently, as do lakes of different depth or productivity. Differences in hydrology and the position in the hydrological flow system, in terrestrial vegetation and land use, in base climates and in the aquatic biota can all cause different responses. Climate change effects interact strongly with effects of other human‐caused stresses such as eutrophication, acid precipitation, toxic chemicals and the spread of exotic organisms. Aquatic ecological systems in the region are sensitive to climate change and variation. 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Hydrogeology</subject><subject>interaction with other stresses</subject><subject>lake ice</subject><subject>Laurentian Great Lakes</subject><subject>north temperate glacial lakes</subject><subject>paleoclimates</subject><subject>physical limnology</subject><subject>phytoplankton</subject><subject>Pollution, environment geology</subject><subject>Precambrian Shield</subject><subject>terrestrial-aquatic linkages</subject><subject>water level</subject><subject>zooplankton</subject><issn>0885-6087</issn><issn>1099-1085</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>1997</creationdate><recordtype>article</recordtype><recordid>eNqFkV1v0zAUhiMEEmXwH3KB0HaR7tj5sF3QhJc6aUSadE0qWG-OstSRCu064k1j_56Elt6AtCtLr5_zno_Xsj4TGBIAen5aJGFyRkAIhwD3T4kQDAIXzggZ8U-c-qORTMbO5Hrmg7hwhzAM84_UiV9Yg2PRS2sAnPtOAJy9tt4Y8x0APOAwsLazvFRZmcjUVlGkwrKw88gO02QqS2WHE5nFqpMyW14tZJmEdnFdlGpajOxULuZ_KjM7nitZdsKXDpXZ2J7NVSinl_P-r5gkKh3bcxUnefbWetVUG6PfHd4TaxGpMpw4aR4noUydyve6mW8CJm7oStCmYdpbcU1ZU_tVUwOIVcO7_QMdeFVDPEJWPVGxmgrNfKBMa75yT6wPe9-7dvfzQZt73K5NrTeb6lbvHgySAAIREHge9LyAcV904Lc9WLc7Y1rd4F273lbtExLAPijEPijsb479zfFvUEgIcuyCQuyCwn1Q6CJgmCPFuLN-f5ihMnW1adrqtl6boz_lvkdd1mHLPfa43uinf9o_2_2_zQ9KZ-7szdfmXv86mlftDwyYy3z8msV4uYyulkFZYOT-BjvmuXY</recordid><startdate>19970630</startdate><enddate>19970630</enddate><creator>MAGNUSON, J. 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We emphasize lakes and quantitative implications. The region is warmer and wetter than it has been over most of the last 12000 years. Since 1911 observed air temperatures have increased by about 0·11°C per decade in spring and 0·06°C in winter; annual precipitation has increased by about 2·1% per decade. Ice thaw phenologies since the 1850s indicate a late winter warming of about 2·5°C. In future scenarios for a doubled CO2 climate, air temperature increases in summer and winter and precipitation decreases (summer) in western Ontario but increases (winter) in western Ontario, northern Minnesota, Wisconsin and Michigan. Such changes in climate have altered and would further alter hydrological and other physical features of lakes. Warmer climates, i.e. 2 × CO2 climates, would lower net basin water supplies, stream flows and water levels owing to increased evaporation in excess of precipitation. Water levels have been responsive to drought and future scenarios for the Great Lakes simulate levels 0·2 to 2·5 m lower. Human adaptation to such changes is expensive. Warmer climates would decrease the spatial extent of ice cover on the Great Lakes; small lakes, especially to the south, would no longer freeze over every year. Temperature simulations for stratified lakes are 1–7°C warmer for surface waters, and 6°C cooler to 8°C warmer for deep waters. Thermocline depth would change (4 m shallower to 3·5 m deeper) with warmer climates alone; deepening owing to increases in light penetration would occur with reduced input of dissolved organic carbon (DOC) from dryer catchments. Dissolved oxygen would decrease below the thermocline. These physical changes would in turn affect the phytoplankton, zooplankton, benthos and fishes. Annual phytoplankton production may increase but many complex reactions of the phytoplankton community to altered temperatures, thermocline depths, light penetrations and nutrient inputs would be expected. Zooplankton biomass would increase, but, again, many complex interactions are expected. Generally, the thermal habitat for warm‐, cool‐ and even cold‐water fishes would increase in size in deep stratified lakes, but would decrease in shallow unstratified lakes and in streams. Less dissolved oxygen below the thermocline of lakes would further degrade stratified lakes for cold water fishes. Growth and production would increase for fishes that are now in thermal environments cooler than their optimum but decrease for those that are at or above their optimum, provided they cannot move to a deeper or headwater thermal refuge. The zoogeographical boundary for fish species could move north by 500–600 km; invasions of warmer water fishes and extirpations of colder water fishes should increase. Aquatic ecosystems across the region do not necessarily exhibit coherent responses to climate changes and variability, even if they are in close proximity. Lakes, wetlands and streams respond differently, as do lakes of different depth or productivity. Differences in hydrology and the position in the hydrological flow system, in terrestrial vegetation and land use, in base climates and in the aquatic biota can all cause different responses. Climate change effects interact strongly with effects of other human‐caused stresses such as eutrophication, acid precipitation, toxic chemicals and the spread of exotic organisms. Aquatic ecological systems in the region are sensitive to climate change and variation. Assessments of these potential effects are in an early stage and contain many uncertainties in the models and properties of aquatic ecological systems and of the climate system. © 1997 John Wiley &amp; Sons, Ltd.</abstract><cop>West Sussex</cop><pub>John Wiley &amp; Sons, Ltd</pub><doi>10.1002/(SICI)1099-1085(19970630)11:8&lt;825::AID-HYP509&gt;3.0.CO;2-G</doi><tpages>47</tpages><oa>free_for_read</oa></addata></record>
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identifier ISSN: 0885-6087
ispartof Hydrological processes, 1997-06, Vol.11 (8), p.825-871
issn 0885-6087
1099-1085
language eng
recordid cdi_proquest_miscellaneous_16069610
source Wiley-Blackwell Read & Publish Collection
subjects aquatic systems
biogeochemistry
chemical limnology
climate change
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Exact sciences and technology
fish
Freshwater
heterogeneity in response
Hydrology
Hydrology. Hydrogeology
interaction with other stresses
lake ice
Laurentian Great Lakes
north temperate glacial lakes
paleoclimates
physical limnology
phytoplankton
Pollution, environment geology
Precambrian Shield
terrestrial-aquatic linkages
water level
zooplankton
title POTENTIAL EFFECTS OF CLIMATE CHANGES ON AQUATIC SYSTEMS: LAURENTIAN GREAT LAKES AND PRECAMBRIAN SHIELD REGION
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