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Trophic State Index
Phosphorus, Chlorophyll-a (algae
concentration) and Secchi depth are related. When phosphorus increases, that means
there is more food available for algae, so algal concentrations increase. When algal concentrations increase,
the water becomes less transparent and the Secchi depth decreases.
The resulting numbers from
these three measurements cover different units and ranges and thus cannot be
directly compared to each other or averaged.
In order to standardize these three measurements to make them directly
comparable, we convert them to a trophic state index using an equation. You can
find the equations online at:
http://dipin.kent.edu/tsi.htm.
The overall trophic state
index (TSI) of a lake is the average of the TSI for phosphorus, the TSI for
chlorophyll-a and the TSI for secchi depth; therefore, it can be thought of as
the lake condition taking into account phosphorus, chlorophyll-a and secchi
depth.
It is important to understand
that Trophic States are defined divisions of a continuum in phosphorus and algal
concentration. The TSI ranges from
0-100. 0-30 is Oligotrophic, where
water is very clear, phosphorus is low, and algae is sparce. 30-50 is an in-between stage where
the number of aquatic plants algae increase due to more available phosphorus.
A TSI of over 50 describes a
lake that is eutrophic, with a high density of plants and algae that could be
unpleasant for swimming at certain times in the summer. Some lakes may be naturally
eutrophic, having a TSI of 50 or greater for the last 100 years. Other lakes have gradually increased
in TSI as a result of human activities.
The Minnesota Pollution Control Agency recommends 8-10 years of quality
long term data on a lake for the determination of increasing or decreasing TSI
trends.
Trophic State Index is not necessarily
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.
Explanation of trophic state
and a list of possible changes that
might be expected in a north temperate lake along the trophic state gradient.
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TSI
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Chl-a(ug/L)
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SD (ft)
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TP (ug/L)
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Attributes
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Fisheries & Recreation
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<30
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<0.95
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>26.2
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<6
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Oligotrophy: Clear water, oxygen throughout the year
at the bottom of the lake, very deep cold water.
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Trout fisheries dominate
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30-40
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0.95-2.6
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13.1-26.2
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6-12
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Bottom of shallower lakes may become anoxic (no oxygen).
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Trout fisheries in deep lakes only. Walleye, Tullibee present.
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40-50
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2.6-7.3
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6.6-13.1
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12-24
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Mesotrophy: Water moderately clear most of the summer. May be "greener" in late summer.
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No oxygen at the bottom of the lake results in loss of trout. Walleye may
predominate.
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50-60
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7.3-20
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3.3-6.6
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24-48
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Eutrophy: Algae and aquatic plant problems possible. "Green" water most of the year.
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Warm-water fisheries only. Bass may dominate.
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60-70
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20-56
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1.6-3.3
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48-96
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Blue-green algae dominate, algal scums and aquatic plant problems.
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Dense algae and aquatic plants. Low water clarity may discourage
swimming and boating.
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70-80
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56-155
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0.8-1.6
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96-192
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Hypereutrophy:
(light limited productivity). Dense algae
and macrophytes.
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Water is not suitable for recreation.
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>80
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>155
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<0.8
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192-384
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Algal scums, few aquatic plants
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Rough fish (carp) dominate; summer fish kills possible
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