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Lake Ontario. Grants No. 0528674 (NSF) and NA06OAR4170017 (NOAA). Created by: Helen Domske, NY Sea Grant. Lake Ontario.
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Lake Ontario Grants No. 0528674 (NSF) and NA06OAR4170017 (NOAA) Created by: Helen Domske, NY Sea Grant
Lake Ontario Lake Ontario is ranked as the 12th largest lake in the world. Lake Ontario’s surface area of 7,340 square miles (18,960 sq km) makes it the smallest of the Great Lakes. Credit: GL Fisheries Commission
Bathymetry of Lake Ontario NOAA GLERL
Lake Ontario Facts The eastern outlet basin of the lake is much shallower and smaller than the main basin. However, with many embayments and peninsulas, the eastern outlet basin accounts for more than 50% of the lake's shoreline. The lake's drainage area is dominated by forests (49%) and agriculture (39%). A total of 7% of the basin is urbanized. Credit: GL Fisheries Commission
Lake Ontario Facts Lake Ontario's current nutrient levels are characteristic of an oligotrophic (low productivity) system. A total of 86% of inflows comes from the upper Great Lakes and Lake Erie through the Niagara River. Water quality is affected by upstream sources and inputs from local industry, urban development, agriculture, and landfills. Credit: GL Fisheries Commission
About 93% of the water in Lake Ontario flows out to the St. Lawrence River; the remaining 7% leaves through evaporation. Source: USEPA
From: A LaMP-based Biodiversity Conservation Strategy for Lake Ontario
Native Migratory Fishes • Lake-tributary fishes: Lake sturgeon, Atlantic salmon, suckers, redhorse, walleye, brook trout • Lake-ocean fishes: American eel • Wetland spawners: Northern pike, muskellunge, and yellow perch From: A LaMP-based Biodiversity Conservation Strategy for Lake Ontario
Photos: H. Domske The WellandCanal connects Lake Erie and Lake Ontario
Welland Canal Facts 1st 2nd 3rd 4th (1829) (1845) (1887) (1932) Number Of Locks 40 27 26 8 Width Of Locks 6.7m 8.1m 13.7m 24.4m Length Of Locks 33.5m 45.7m 82.3m 261.8m Depth Of Canal 2.4m 2.7m 4.3m 8.2m The building of the canal was a labor intensive venture. Construction crews\ made up of European immigrants had very few tools to work with other than picks and shovels. The men on these crews were paid about a half a dollar for a day's work. The operation of the canal also required a great deal of physical labor as horses and oxen were used to tow the ships (schooners) from one lock to another on paths that still exist today as streets by the name of towpath. The total cost of the canal was 8 million dollars and the man responsible for initiating the project was a young entrepreneur by the name of William Hamilton Merritt. He would later become known as the founding father of the Welland Canal. From: http://www.wellandcanal.com
Lake water levels are influenced by dams and locks in the St. Lawrence River.
Ecosystem Restructuring: The Culprits – Zebra & Quagga Mussels Photos: DFO Credit: SOLEC 2011
In Lake Ontario the dominant attached alga is Cladophora. In the 1960s and 1970s this alga caused serious problems in the near shore zone. It had explosive growth, which detached and fouled local beaches at the peak of the summer recreational season. Research at that time showed that Lake Ontario was receiving an excess of phosphorus, which normally limits Cladophora growth in the shallow, well-illuminated near shore zone. Credit: Ontario Water Works Research Consortium
Cladophora Credit: Ontario Water Works Research Consortium
Nearshore Zone Food Web and Fisheries Highlights • Although zebra mussels once dominated the nearshore zone, they are now found primarily in water less than 10 feet deep. Quagga mussels now dominate the lake bottom from the water's edge to depths beyond 400 feet. • At the base of the food web, the abundance of green algae (phytoplankton) is lower than what would be expected for the current level of phosphorus (plant nutrient) in the water due to the effects of zebra and quagga mussels. • Spring abundance of diatoms, a microscopic algae that is an important food source for zooplankton and opossum shrimp (Mysis), has declined in the Eastern Basin since the establishment of zebra and quagga mussels. Mysis shrimp Source: NYS Department of Environmental Conservation
Early Commercial Pressures • Commercial fishing practices are also partially to blame for the demise of Atlantic salmon in Lake Ontario. • Spawning salmon were captured or hindered by pound nets and weirs.
Native Lake Ontario Fishes: 100 Years Ago Whitefish Lake Trout Lake Herring Atlantic Salmon
The Historic Fish Community in Lake Ontario Atlantic salmon Emerald shiner Lake whitefish Planktivores Lake trout Blue pike Lake herring Bloater Walleye Burbot Predators Yellow perch White bass Lake sturgeon American eel Deep-water sculpin Benthic Bullheads/Catfish Bowfin Smallmouth bass Slimy sculpin Credit: Dave McNeill, NYSG
The Present Lake Ontario Fish Community Alewife Sea lamprey Non-native fish species Native: abundant Rainbow smelt Blueback herring Round goby Common carp White perch Brown trout Atlantic salmon* Chinook salmon Lake trout* Native: reduced Coho salmon Intentionally stocked Rainbow trout Credit: Dave MacNeill, NYSG
Enter the “Evil Alewife”: a Paradox It looks benign, but it has been a serious nuisance species and a benefit!? Mass die-offs Credit: Dave MacNeill, NYSG
Important Time Periods for Lake Ontario Fisheries: • Early-late 1800s:Welland Canal system, lamprey enter, watershed changes: deforestation, damming, siltation, unregulated salmon fishing, alewives introduced, salmon collapse and extirpated. • 1920s and 1930s:Sea lamprey predation, highly-prized fish populations collapse, increased harvest on alternative fish species, introduction of smelt and double-crested cormorant, smelt and alewife dominate offshore, alewife die-offs, human population growth, industry, nutrient inputs. • 1950s and 1960s:Population collapses of many native species, severe decline of lake trout/burbot, St. Lawrence Seaway opens, TFM used for sea lamprey control, massive alewife die-offs, contaminant loadings, hydroelectric power use, successful stocking, concern for nutrient loading, double-crested cormorants decline. Credit: Dave MacNeill, NYSG
Important Time Periods for Lake Ontario Fisheries: • 1970s and 1980s:Beginning/expansion of stocking efforts, sportfisheryworth millions of dollars, alewives and smelt under some control, invasive species introductions by ballast water, nutrient/toxic abatement, signs of successful lake rehabilitation. • 1990s and early 2000s:Stocking rates/sportfisheries peak & decline, more ballast invasions with negative impacts on fish/ecosystems, double-crtested cormorant populations explode, alewife/smelt decline, signs of successful lake trout reproduction, fisheries sustainability? Credit: Dave MacNeill, NYSG
Results of Human Impacts on Lake Ontario Fish Communities: • A shift from dominant species that are large and long-lived (i.e. lake trout, Atlantic salmon, lake sturgeon) to smaller, short-lived fish species. • A shift in populations with relatively stable populations (numbers and age) to unstable populations that fluctuate considerably (numbers/ages). • A shift from populations with diverse habitat preferences and diverse physical characteristics to populations that thrive only in narrow range of habitats. • A shift in abundance of highly-prized, commercial fish species for human food, to species to fish species that are of little or no commercial value. Credit: Dave MacNeill, NYSG
The Niagara River is the connecting channel between Lake Erie and Lake Ontario and a major source of hydroelectricalgeneration.
Wetlands are important habitats on Lake Ontario and serve as spawning areas for a number of fish species.
Tourism plays an important role in the economy around Lake Ontario. The Seaway Trail National Scenic Byway brings tourists to the area.
Double-Crested Cormorants New York State used "oiling" of cormorant eggs to prevent their hatching. DEC also destroys nests and "hazes" nesting areas in spring and fall to try to prevent the birds from feeding on fish. Double crested cormorants can have negative impacts on islands and other habitats where they nest. Their excretions and nesting activities destroy ground vegetation and trees around nest, eliminating habitat for other birds and animals. There are reported cases where cormorants have displaced other colonial nesting species such as great blue herons, common terns and black-crowned night herons from their nesting sites.
Double-Crested Cormorants One of 6 cormorant species native to North America, 35 worldwide, only species typically found inland. First nested in Eastern Lake Ontario in 1945. Populations grew, by 1970 was 125 pairs in all the Great Lakes and at one point reached 750,000. Connie Adams, NYSDEC
Cormorant Prey Species Connie Adams, NYSDEC
Bald Eagle • Indicator Species • Nesting Habitat Restoration Efforts • 43 prime nesting sites identified in Ontario and New York • Eight nesting platforms constructed Photo: OMNR