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Lake
Trophic States
Scientists like to classify lakes
and give names to the different lake types so they can be easily referred to. Trophic states are based on lake fertility.
The root "trophy" means nutrients; therefore, lakes are classified based
on the amount of available nutrients (Phosphorus and
Nitrogen) for organisms.
More fertile lakes have more nutrients and therefore more plants and
algae. Most of the
lakes in
Minnesota
were formed as the glaciers receded, carving out basins in the landscape.
In these newly formed lakes, the edges and bottom are exposed rock, which
doesn't erode very quickly, meaning there are not many nutrients available. As a lake ages, sediment from the watershed
is washed in, filling in the bottom of the lake.
This sediment is rich in nutrients, and therefore also increases the fertility
of the lake.
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Oligotrophic
"Oligo" means very little; therefore,
oligotrophic means very little nutrients (Phosphorus
and Nitrogen).
Oligotrophic lakes are usually found in northern
Minnesota
and have deep clear water, rocky and sandy bottoms, and very little algae.
The fish found in oligotrophic lakes
like cold, high oxygenated water, examples include lake trout and whitefish (more information on fish).
In oligotrophic lakes, oxygen
is found at high levels
throughout the water column. Cold water
can hold more dissolved oxygen than warm water, and the deep region of oligotrophic
lakes stays very cold. In addition,
low algal concentration allows deeper light penetration and less decomposition.
When algae, zooplankton and fish die,
they sink to the bottom and are decomposed by microbes and invertebrates.
This decomposition process uses up oxygen.
Since oligotrophic lakes are less fertile and have less algae and other organisms,
there is less decomposition and the oxygen doesn't get used up. |
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mesotrophic
"Meso" means middle or mid; therefore,
mesotrophic means a medium amount of nutrients (Phosphorus
and Nitrogen).
Mesotrophic lakes are usually found in central
Minnesota
and have clear water with some algal blooms in late summer.
Mesotrophic lakes are great fishing
lakes and are home to many sport fish such as walleye, perch, smallmouth bass, muskellunge
and northern pike (more information on fish).
Mesotrophic lakes behave differently
than oligotrophic lakes in that they stratify, meaning they separate into layers
in the summer (more on lake stratification).
The top layer of water becomes warm from the sun and contains algae.
Since the by-product of photosynthesis is oxygen,
oxygen concentration remains
high at the surface of the lake. The
bottom layer remains cooler and can become anoxic in mid-summer.
This change occurs because as all the algae and other organisms die and are
decomposed at the bottom of the lake, oxygen gets used up.
Since this bottom layer of water does not mix with the top layer of water
in the summer, oxygen cannot be replenished.
The implications of anoxia are that no fish or other organisms can live where there
is no oxygen; therefore, in late summer, fish move shallower where there is still
oxygen available.
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eutrophic
"Eu" means true; therefore, eutrophic
literally means true nutrients or truly nutrient rich (Phosphorus
and Nitrogen). Eutrophic lakes are found in southern
Minnesota
where the soils are more fertile and where there is a lot of farmland.
Eutrophic lakes are shallow and have murky water and mucky, soft bottoms. They also have a lot of plants and algae
(more information on eutrophication).
In less eutrophic lakes, common
fish include largemouth bass, northern pike, perch and panfish.
As a lake becomes increasingly eutrophic, sport fish dwindle and carp abound
(more information on fish).
Eutrophic lakes are very fertile
from all the nutrients carried into the lake from the surrounding landscape. These nutrients (Phosphorus
and Nitrogen)
support high densities of algae, fish and other aquatic organisms.
Since eutrophic lakes have so much biomass, there is a lot of decomposition
occurring at the bottom. This decomposition
uses up oxygen, causing the bottom of the lake to become anoxic in the summer. In very shallow lakes, the whole lake
can become anoxic, causing a fish kill.
Fish, invertebrates and other organisms need oxygen to survive.
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Some lakes may be naturally eutrophic for the past 100 years. Other lakes have gradually increased
in nutrients as a result of human activities and have gone from mesotrophic to
eutrophic. The divisions of the trophic
state index for each trophic state are roughly: 0-30 Oligotrophic, 30-40
Oligotrophic/Mesotrophic, 40-50 Mesotrophic, 50-70 Eutrophic, 70+
Hypereutrophic. (see more information about Trophic State Index)
One drawback of defining trophic states as certain divisions in the trophic
state index is that each lake is different. The trophic nature of a lake depends on many things including depth,
area, watershed size, adjacent land use, and climate. A lake with a TSI of 49 falls on the
borderline between mesotrophic and eutrophic, and there is some overlap. Trophic states should be
considered a general definition of lake condition.
It is important to remember that lake trophic state is not
interchangeable with water quality.
Water quality is subjective and depends on how you intend to use the water body.
A lake that is good for duck hunting is not necessarily good for water skiing. In turn, a lake that is great for
swimming may not be great for bass fishing.
For more information on trophic states, visit:
http://dipin.kent.edu/trophic_state.htm. |
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