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"Identifying
Wetlands" Lesson Plan
Keywords: water
plants, wetlands, hydrology
Prepared by: Jeff
Kerr, Tidioute Area School District
Grade Level: ninth through
twelfth grade
Time Required:
85-minute period (not including follow-up activities)
Materials Needed
- field guides of grasses,
sedges, rushes, and other plants; Pond Life (A Golden Guide)
is a useful guide for both ponds and emergent wetlands
- shovel and/or auger
- containers for samples
(optional)
Goals of the Lesson
- The students will
be able to list and describe the three major categories of indicators
used to delineate wetlands (hydrology, vegetation, soils)
- The students will
be able to identify hydrologic features that can be used to identify
wetlands during a field inspection
- The students will
be able to list and identify several plants associated with wetlands
- The students will
be able to describe and identify a wetland soil.
Background Information
Since Pennsylvania was
settled by Europeans, the state has lost over 50 percent of its
wetlands. Wetlands serve several vital functions, including providing
wildlife habitat, providing flood control, reducing pollution by
sedimentation and by plants removing excess nutrients and toxic
chemicals, and reducing erosion. Although there are many different
types of wetlands, the Pennsylvania Department of Environmental
Protection lumps wetlands into three major categories: forested
wetlands, scrub-shrub wetland, and emergent wetlands (vegetated
by herbaceous plants). ("An
Introduction to Wetlands," DEP Fact Sheet; "Wetlands
Values and Trends," NRCS/RCA Issue Brief 4)
There are three major
categories used to identify and delineate wetlands: vegetation,
soils, and hydrology. ("Recognizing Wetlands," U.S. Army
Corps of Engineers) The following lesson is designed to help students
understand these categories.
Procedure
- Take your students
to a nearby wetland. The ideal situation would be to go to an
old beaver pond or other pond that is slowly filling in. However,
it is possible to make due with an undredged, unmowed ditch that
often has standing water or another wet area.
- Have the students
look at the area in general. Ask them if they have an idea where
the wetland is and how they know. They may see standing water,
sediments on leaves and other objects, water marks on trees, or
drift lines. Pull out a plant and have the students observe the
roots. They may see rust marks because oxygen has leaked out of
the roots and caused iron in the soil to rust. This type of evidence
is known as hydrologic evidence, signs that the soil is frequently
saturated with water or flooded.
Note: Often drainage
is affected by a fragipan (hard-pan), which is a layer of soil
compacted so tightly that it won't even let most roots penetrate.
- Some of the students
may have also noticed the differences in plants. field guides
or some other reference. Some plants common to wetlands in this
area include sedges, rushes, horsetail, skunk cabbage, marsh marigold,
cattails, sensitive fern (Onoclea), willows, elderberry, red osier
dogwood, red and silver maples, American hornbeam (musclewood),
and sweet birch. Sedges have triangular stems and three-ranked
leaves. Rushes have hollow or pith-fitted round stems with usually
hollow leaves. Some plants called rushes, such as beaked rushes,
are actually sedges. Some of the plants observed can only be found
in wetlands; others can be found both in wet and dry areas.
- Dig up some of the
soil in the wetland and have the students describe it. They may
observe a top layer of black "muck," which is organic
matter that decays slowly due to the lack of oxygen. They may
also notice a foul odor caused by sulfur compounds formed by anaerobic
bacteria. Below the muck, they should notice that the soil is
mostly gray. Most students mistakenly believe that gray means
that it is clay. Although the soil may be higher in clay content,
often it is not considered a clay soil. Texture the soil by the
"feel method" (handout
by S. J. Thien). The gray soil is called "gley" and
it occurs when anaerobic bacteria reduce iron in the soil. Since
many of the students don't know about oxidation and reduction,
I usually tell them that the bacteria take the oxygen out of the
rust to get iron. I then reinforce this concept by asking them
the color of an iron object (gray). I then ask them what happens
when the iron is exposed to water and air. (It rusts; oxygen from
the air reacts with iron.) I then explain that the bacteria do
the opposite by taking the oxygen out of the rust.
- Dig some soil at the
edge of the wetland. Patches of gray and rust should be observed.
These patches are called mottles. This is where the soil is saturated
for part of the year and exposed to air for part of the year.
This part of the soil is known as the "seasonal water table".
Where the soil is a solid gray color, it is known as the "permanent
water table."
- Give the students
a brief quiz at the end of the lesson or the next day.
- Ask them to give
a few hydrologic features of a wetland.
- Have them identify
some of the most common wetland plants observed. Ask them
how to distinguish a sedge and a rush from a grass.
- Ask them what
is the color of the mineral portion of the soil in the permanent
water table and why it is that color.
- Ask them why the
seasonal water table soil has mottles of gray and rust.
Possible Follow-Up
Activities
- If your wetland did
not have a variety of plants, bring in specimens of common wetland
plants.
- Take two dry samples
of soil. Mix one with a little soil from a wetland. Saturate both
samples with water, cover the sample, and observe what happens
over the next few weeks. The soil mixed with the wetland soil
should turn gray; whereas the regular soil should not. This is
due to the presence of certain anaerobic bacteria in the wetland
soil. This should demonstrate that gleying is a biological process.
- Use a soil survey
book of your county to locate possible wetlands in your area.
Wetland soils are called hydric soils and are usually poorly drained.
Drainage classes are defined based on the depth to mottles (of
gray and rust) from the surface of the mineral soil (not including
organic matter on the top).
| Drainage classes
|
Depth to mottling
|
| Poorly drained |
0-8 inches (sometimes
completely gleyed) |
| Somewhat poorly
drained |
8-18 inches |
| Moderately well
drained |
18-36 inches |
| Well drained |
> 36 inches |
Note: Often drainage
is affected by a fragipan (hard-pan), which is a layer of soil so
tight that it won't even let most roots penetrate.
References
"An
Introduction to Wetlands," DEP Fact Sheet.
"Recognizing Wetlands,"
U. S. Army Corps of Engineers, 1998.
Reid, George K. Pond
Life. Golden Guide Publishing Company, Inc., 1995.
Thien, Steve J. "A
Flow Diagram for Teaching Texture-by-Feel Analysis, "Journal
of Agronomic Education. Vol. 8, 1979, pp. 54 - 55.
"Wetlands Values
and Trends," NRCS/RCA Issue Brief 4, United States Department
of Agriculture and Natural Resources Conservation Service, November
1995.
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