Tag Archives: Ecosystem

Lake Champlain Phosphorus Levels (20 year chart)

Lake Champlain Phosphorus Levels for past 20 years

Lake Champlain Phosphorus Amounts Chart image

Amounts of Lake Champlain Phosphorus

This chart created by the Addison Independent from Vermont Agency of Natural Resources, Water Management Division data shows the number of metric tons of Phosphorus in Lake Champlain per year from 1991 through 2011. The chart focuses on three Vermont watersheds, namely Otter Creek, the Winooski River and the Missisquoi River.

Last year’s record spring flooding and Tropical Storm Irene caused unprecedented amounts of phosphorus to be dumped into Lake Champlain. In some cases the amounts were two to three times the average high mean levels. These high Phosphorus levels are responsible for the widespread and sudden appearance of Blue-Green Algae, or cyanobacteria blooms that have closed beaches around the Lake.

“Phosphorus is key to causing the dense cyanobacteria blooms,” according to Angela Shambaugh, aquatic biologist for the Water Management Division at the Vermont Agency of Natural Resources and a leading authority on cyanobacteria. “That bulk of algae really can’t grow without phosphorus, and it takes a lot of phosphorus to create that amount of biomass.”

In Vermont, cyanobacteria live in warm, shallow waters that get lots of sun and low winds. And they flourish most where their primary source of food – phosphorus – is most abundant. As the above chart illustrates, Lake Champlain Phosphorus levels have never been higher. Warmer weather and calmer wind and waves provide the ideal conditions for the formation of Blue-Green Algae blooms and have contributed to our current outbreaks.

Lake Champlain phosphorus levels lead to Blue-Green Algae Bloom

Boaters, swimmers, water-skiers, waders, parents, pet-owners and residents should become familiar with the appearance of blue-green algae (cyanobacteria). Avoid contact with dense accumulations of these algae. Children are at higher risk because they are more likely to drink the water. Pets should not be allowed in algae-contaminated water, because they will also drink the water and consume algae on their fur.

For more information on the causes, dangers and prevention of Blue-Green Algae blooms see Blue-Green Algae Tips.

Further Reading:

Blue-Green Algae Tips, (LakeChamplainLife.com)

Lake Champlain Blue-Green Algae Bloom Status Map, (Vt Dept. of Health)

Lake Champlain, Environmental Reports, (VT ANR)

Blue-green Algae, Information Bulletin, (NYS Dept. of Health)

Cyanobacteria (blue-green algae) in Vermont, (VT ANR)

Blue-green algae and our surface water, (MDDEP, Quebec)

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Blue-Green Algae Tips

Blue-Green Algae Tips for Lake Users

Blue-green algae bloom

Blue-green algae or Cyanobacteria, is a common and natural component of the microscopic plants (plankton) in Lake Champlain and other waters. Some blue-green algae produce natural toxins or poisons. When the algae die and decompose, toxins can are sometimes released into the water.

Blue-green algae are an ancient group of algae. Although they are most closely related to other bacteria, they can photosynthesize like green plants. Blue-green algae reproduce rapidly in lakes and ponds with adequate amounts of sunlight, air/water temperature andnutrients like phosphorus and nitrogen.

Blue-green algae can become very abundant in some sections of Lake Champlain as the water warm in mid-summer. Particular problem areas are Missisquoi Bay and St. Albans Bay. Under calm conditions, the blue-green algae can accumulate in thick layers on the surface or along the shoreline. These accumulations are often referred to as “blooms” or “scums.” Although blue-green algae blooms can create nuisance conditions and undesirable water quality, most blooms are not toxic.

For much of the year, Lake Champlain is safe to swim in, but it is important to be aware of algae blooms. Blue-green algae blooms usually don’t occur until July, and are most common in August and September.

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Is Blue-Green Algae Really Dangerous?

While there are no documented cases of human illness due to blue-green algae in Lake Champlain, caution around the algae is urged, especially for pet owners. If animals ingest the toxins, they can become paralyzed and die quickly. The signs of such poisoning include weakness, staggering, difficulty breathing, convulsions and death.

Some blue-green algae produce toxins that could pose a health risk to people and animals when they are exposed to them in large enough quantities. Health effects could occur when surface scums or water containing high levels of blue-green algal toxins are swallowed, through contact with the skin or when airborne droplets containing toxins are inhaled while swimming, bathing or showering.

Recreational contact, such as swimming, and household contact, such as bathing or showering, with water not visibly affected by a blue-green algae bloom is not expected to cause health effects. However, some individuals could be especially sensitive to even low levels of algal toxins and might experience mild symptoms such as skin, eye or throat irritation or allergic reactions.

During the summers of 1999 and 2000 the death of two dogs was attributed to blue-green algae poisoning, after drinking large amounts of contaminated water directly from the lake.

While blue-green algae toxins have been detected at many locations in Lake Champlain, the highest concentrations of toxins are usually found in blooms and shoreline scums. These dense accumulations pose the greatest potential health risks. Watch for dense accumulations of algae and avoid these areas.

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How Does Weather Affect Blue-Green Algae Blooms?

Surface water affected by blue-green algae can be so strongly colored that it can develop a paint-like appearance.

The warmer water temperature results in an increase in the amount of blue-green algae and the presence of blooms.

Weather can also influence where blue-green algae will accumulate. During extended periods of calm and sunny days, blooms can accumulate at the surface in any location. Wind and waves may cause them to form along shorelines or in protected areas. Shifts in wind direction can move a bloom from one location to another.

Periods of cool rainy weather can often lead to the disappearance of a bloom.

Properties of Blue-Green Algae Blooms

The water may appear cloudy and look like thick pea soup.
Blooms are generally green or blue-green in color, although they sometimes can be brown or purple.
A thick mat or foam may form when a bloom washes onto shore.
large numbers of dead fish, waterfowl or other animals.
sudden, unexplained sickness or death of a cat or dog.
a skin rash on humans after being in the water.
Not all blue-green algae produce toxins, however there is no way to tell just by looking at them.
View this Vermont Dept. of Health photo gallery for what a Blue-green algae bloom looks like

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What Can You Do To Avoid Blue-Green Algae?

Boaters, swimmers, water-skiers, waders, parents, pet-owners and residents should become familiar with the appearance of blue-green algae. Everyone should avoid contact with dense accumulations of these algae.

Children are at higher risk because they are more likely to drink the water.

Do not allow pets in algae-contaminated water because they will also drink the water and consume algae on their fur.

If your dog does swim in a bloom, wash the dog off when it comes out of the water; make sure the dog does not lick the algae out of its fur.

If the water has a lot of algae in it, make sure the dog drinks from another source.

If you believe that someone has become ill because of blue-green algae, please contact the VT Department of Health at 800-439-8550 or the NYS Department of Health at 518-402-7820.

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How Can You Help Prevent Blue-Green Algae Blooms?

Sometimes blue-green algae becomes so abundant that it forms floating rafts or scums on the surface of the water.

Algae blooms typically occur during sunny, calm weather when high concentrations of nutrients are present in water. The two important nutrients that can cause a bloom are phosphorus and nitrogen, found in animal and human waste and fertilizers.

To help decrease nutrients flowing into streams, ponds and lakes:

Don’t use more lawn fertilizers than the recommended amount, and keep fertilizers out of storm drains and off driveways and sidewalks.
“Don’t ‘P’ on the lawn!” It’s the Law! New laws in Vermont and New York that took effect January 1, 2012, prohibit the application of phosphorus fertilizers except in certain circumstances.

Maintain or plant native plants around shorelines and streams. Native plants don’t require fertilizers and help filter water.

Properly care for and maintain your septic system.

Do not allow livestock to drink or defecate in streams or lakes. Don’t overfeed waterfowl.

Take steps to prevent soil erosion.

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* Check the Current Lake Champlain B-G Algae Status Map Here *

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How You Can Prevent Invasive Species Expansion

We’ve examined the vast variety of invasive species that are posing threats to Lake Champlain’s ecosystem. By now you’re wondering , “What can I do to prevent invasive species expansion?”

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What Can You Do?

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Boat Owners:

Inspect your boat

If you are a boat owner, make sure whenever you move your boat from one body of water to the other that it is free of zebra mussels, one of the most dangerous and invasive of all the species. The larval stage of zebra mussels is microscopic in size so you cannot necessarily see them.
Clean your boat off when it has come in contact with infested bodies of water, and give it a good look over. Throw any zebra mussels you find in the trash.
Remove all mud, plants, or animals and dispose of on dry land.
Drain all bilge water, live wells, bait buckets, and all other water from your boat, engine and equipment.
Wash all parts of your fishing gear and boat that have been in contact with water. Do not allow wash water to flow into any body of water or storm sewer.
Drain all water from the boat, including the bilge, live well, and engine cooling system. Dry the boat and trailer in the sun for at least five days, or if you use your boat sooner, rinse off the boat, trailer, anchor, anchor line, bumpers, engine, etc. with hot water or at a car wash.

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Anglers:

Don’t move fish from one body of water to another.
Never release unused bait fish, even in waters where using them is allowed.
Never move fish overland, unless they have been certified as being disease-free.

Make sure that your boat and equipment are clean and dried before using them in a different waterway.
Inspect all parts of your fishing gear, boat, and trailer that have been in contact with water.

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Everyone:

Learn more about invasive species. A great resource is the Lake Champlain Basin Program’s Aquatic Invasive Species Guide (free download).

Purchase non-invasive plants and fish for your landscapes and aquarium.
Don’t release unwanted plants or animals into the wild.
When swimming or boating in an area infested with Eurasian water milfoil, try not to break parts off the plant—this is how the plant spreads.

Participate with these organizations that are active in protecting Lake Champlain. Here are some places to start:

Additional Infomation:

Invasive Aquatic and Wetland Animals (Invasive Species) by Suellen May
Invasive Aquatic and Wetland Plants (Invasive Species) by Suellen May
Invasion Ecology by Julie Lockwood, Martha Hoopes and Michael Marchetti
Invasive Plants: Guide to Identification and the Impacts and Control of Common North American Species by Sylvan Ramsey Kaufman and Wallace Kaufman

Other Invasive Threats to Lake Champlain

We’ve looked at fish, mollusks, crayfish and plants that want to make Lake Champlain their home. Here are some other invasive threats to Lake Champlain:.

Hemorrhaged Walleye

VHS: viral hemorrhagic septicemia: an often lethal fish disease affecting many species. VHS in the Great Lakes drainage has led to significant restrictions on transporting fish between water bodies. It is so significant that new outbreaks must be reported to the World Health Organization for Animal Health. The disease transmits easily between fish (both individuals and species) and mortality rates seem to be highest in colder waters (37-54 F). Because some fish can be carriers of the virus and show no external signs, the actual presence of the disease can only be determined by laboratory testing.

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Spiny water flea and fishhook water flea:

These two plankton species could drastically disrupt Lake Champlain’s food web. Spiny water flea and fishhook water flea both came from Northeast Europe; they were first noticed in Lake Huron in 1984 and Lake Ontario in 1998. These two species were most likely released with a ship’s ballast water. In 2008 spiny water flea were found in the Great Sacandaga Lake in New York, just upstream from the feeder for the Champlain Canal.

** Since this article was originally published (June 11, 2012), Spiny Water Fleas have been confirmed in the Champlain Canal and in Lake George; both of these waterways are linked directly to Lake Champlain. It now (August3, 2012) seems inevitable that Spiny Water Fleas will become established in Lake Champlain, if they haven’t already.

Spiny Waterfleas collect in masses on fishing lines.

In addition to competing with the native zoo-plankton, spiny water flea and fishhook water flea are much more difficult for small fish to ingest, and are therefore a poorer food source. The long spines of these species can hook them onto anglers’ lines by the hundreds, making fishing difficult. Eggs and adult water fleas can travel unseen in a boat’s bilge water, bait buckets, and live wells.

Learn to recognize these water-fleas on fishing gear.

Inspect and remove aquatic plants and animals, including gelatinous or cotton batting-like material from lines, especially where they meet a swivel, lure or down-rigger ball connection (plucking like a guitar string helps).

Drain lake or river water from live-well and bilge before leaving access.

Dispose of unwanted live bait and worms in the trash.

Double-crested Cormorants

Double-crested Cormorants: Cormorants are relative newcomers to Lake Champlain and have since become a concern to wildlife managers. They first nested on Young Island, Vermont, in 1981; then expanded to Four Brothers Islands, New York, by 1984, and peaked at over 20,000 birds by 1999. Population increases were associated with destruction of vegetation and displacement of other birds from nesting colonies of stick nests built high in trees on islands or in patches of flooded timber. .

Gangly Double-crested Cormorants are prehistoric-looking, black fishing birds with yellow-orange facial skin. Though they look like a combination of a goose and a loon, they are relatives of frigatebirds and boobies.

Double-crested Cormorants float low on the surface of water and dive to catch small fish. After fishing, they stand on docks, rocks, and tree limbs with wings spread open to dry. In flight, they often travel in V-shaped flocks that shift and reform as the birds alternate bursts of choppy flapping with short glides..

Obviously, Lake Champlain is a great lake; who could fault these newcomers for wanting to take up residence here? But these invasive species are threats to the health and survival of our native species, and will disrupt the health, recreation and aesthetic enjoyment of Lake Champlain’s human residents. We must protect our lake; so, what can we do…?.

Next: What Can You Do to Protect Lake Champlain? ( Next >> )

Previous: Invasive Invertebrates ( << Previous )

Invasive Plants

Plant Invaders

Invasive plants are non-native species that are capable of moving or, more likely, being moved into a habitat and then monopolizing resources such as light, nutrients, water, and space at the expense of and to the detriment of other species. They are more aggressive and successful than native species at dominating the available resources.

Invasive Plants in the Lake Champlain Basin

Hydrilla

Hydrilla (Hydrilla verticillata): is a highly aggressive plant. Hydrilla has clogged drainage canals in the southeast and it’s been reported as close as Massachusetts, Maine, and southern New York. Fragments falling from boats, trailers, and live wells can start new populations, which often begin near boat launches.Hydrilla was first introduced to the United States as a popular aquarium plant, which was then accidentally released into the wild in Florida. Hydrilla is capable of completely clogging waterways. Its vertical branches often out-compete native plants, affecting water quality and restricting flow. The widespread growth of this plant has dramatic impacts on recreational uses such as boating, fishing and swimming.Compared to other aquatic plants, Hydrilla grows well in deeper, darker waters and new infestations may establish a foothold there before spreading into shallower waters and out-competing other resident plants..

Eurasian Milfoil

Eurasian Water milfoil (Myriophyllum spicatum), first discovered in the Basin in 1962, is found in many areas throughout the Lake and Basin. In some areas infestations are severe. Detailed watermilfoil studies have been conducted for many of Lake Champlain’s bays and for 35 other lakes within the Basin, but many areas have little or no study regarding the presence and extent of infestation. Because Eurasian water milfoil is spread by plant fragments transported by waves, wind, currents, people, and to some extent, animals, it is not easily controlled.

Variable-leaved Milfoil (Myriophyllum heterophyllum) : Related to Eurasian Water milfoil was found in 2009 in Missisquoi Bay; it too can become a nuisance. Because milfoil spreads by stem pieces, roots and seeds, plant parts can easily hitchhike on recreational equipment if not removed. Boaters are advised to avoid beds of watermilfoil to prevent spreading the plant further. Boaters, anglers and other recreational enthusiasts should take precautions to avoid transporting this and other invasive species to other waters or other parts of Lake Champlain.

Japanese Knotweed

Japanese knotweed (Polygonum cuspidatum) was first introduced to the United States as an ornamental plant in the late 1800’s for its appealing flowers. It was also used for erosion control because of its prolific growth. It has since spread into the wild across the United States, including the Lake Champlain Basin. It spreads by underground rhizomes that easily fragment and spread to other areas. This is a problem especially along stream banks where natural forces contribute to the spread of knotweed.

Japanese knotweed has already altered the natural characteristics of the Lake Champlain Basin. Since it grows early in the season and is very dense, it excludes the growth of native plant species. When dense stands are removed from river banks there can be increased erosion until native plants are able to reestablish themselves.

European Water Chestnut

European water chestnut (Trapa natans), first documented in Lake Champlain in the 1940s, displaces other aquatic plant species, is of little food value to wildlife, and forms dense mats that change habitat and interfere with recreational activities. Water chestnut is a fierce competitor in shallow waters with soft, muddy bottoms. Uncontrolled, it creates nearly impenetrable mats across wide areas of water. In South Lake Champlain, many previously often fished bays are now inaccessible and floating mats of chestnut can create a hazard for boaters. This noxious plant also blocks light into the water, a critical element of a well-functioning aquatic ecosystem, reduces oxygen levels which may increase the potential for fish kills.

Submersed leaves are feather-like; each leaf is divided into segments that are whorled around the leaf stem. White flowers form in the axils of the surfacing leaves in July. Fruit are nut-like and “woody” with typically four sharp, barbed spines. Long cord-like rarely branching stems can attain lengths of up to 16 feet. Water chestnut grows in freshwater lakes and ponds and slow moving streams and rivers. It prefers calm, shallow, nutrient-rich waters.

Didymo or ‘Rock Snot’

Didymo: Didymosphenia geminata, commonly referred to as “didymo” or “rock snot” is a freshwater algae. Native distribution of the species includes cool temperate regions of Northern Europe and Northern North America. While not much of a threat to Lake Champlain itself, didymo may pose a threat to rivers and streams because it can form dense mats in stream beds. Scientific studies conducted around the world have yet to show that didymo has significant impacts to salmon and trout.

Didymo attaches to the streambed by a stalk. It has a rough texture similar to wet wool and mimics strands of toilet paper, as opposed to other species of algae which feel slimier.

Didymo can be accidentally spread by people using rivers, as its microscopic cells can cling to boats, waders, fishing gear, sandals, and anything else that comes in contact with water. Gear must be dried for a minimum of 48 hours or cleaned with a bleach solution to get rid of the algae.

What else poses a threat to Lake Champlain’s ecosystem?

Lake Champlain Life

Exploring Life on and Around Lake Champlain