Soil: A marriage of science and math?
Panhandle Math-Science Teachers' Conference
September 20, 2008, West Texas A&M University, Canyon, TX
http://www.wtamu.edu/~crobinson/DrDirt/WT_MSTC08a.html
Dr. Dirt's K-12 Teaching Activities
Links will open in new windows.
The Apple as Planet Earth: A quick, simple illustration using an apple to help students understand the importance and limited nature of the soil resource. The earth is shared with about 6.8 billion people, who depend on to produce all the food, fiber and lumber to feed, clothe, and shelter them all, so that the populace does not end up hungry, naked and homeless.
You need an apple and a knife (sharp enough to easily cut the apple). The basic facts you need to complete the demonstration include:
     Approximately 70% of the earth's surface is covered with water (simplify it for cutting an apple to about 75%, three-fourths)
     Half of the part that is not water is in polar ice caps and high mountain ranges (1/2 of 1/4 - note use of math skills, 1/8 remains)
     Of the remaining 1/8, 3/4 of it is too hot, too cold, too steep, too shallow, too wet, too dry, or has some other problem so that it
         cannot be used to produce the food, fiber and lumber to help feed, clothe, and shelter the 6.8 billion people on the planet. This
         leaves 1/4 of 1/8, or 1/32 of the earth's surface that is used in food, fiber and lumber production.
     Actually, though, the soil is only the thin skin (peel a fraction of the remaining slice, so that the peel hangs down), the surface
         1 to 2 meters, which is the part used to produce the food, fiber, and lumber.
     Each year, the population grows, and the soil available for food, fiber, and lumber production decreases due to desertification,
         salinization, sodification, urban sprawl and industrial development, etc. So, farmers around the world have to produce more and
         more food on less and less land every year.
Use math to determine the appropriate fractions. then determine the approximate area for each fraction of the earth's surface: water, polar ice caps and high mountain ranges, poor land, productive land. The approximate surface area of the earth is 510,065,600 km2 or 196,940,400 square miles.
The 1-minute video is found on the American Farmland Trust website (at the bottom).  In case the link does not work, the url is: http://www.farmland.org/#.
TEKS:
   Grade 1: 112.3.b1B
   Grade 2: 112.4.b1B, 10B
   Grade 3: 112.5.b1B, 3C, 11A
   Grade 4: 112.6.b1B, 3C
   Grade 5: 112.7.b1B, 3C
   Grade 6: 112.22.b1B, 3C
   Grade 7: 112.23.b1B, 2A
   Grade 8: 112.24.b1B
   Env Sys: 112.44c5A
Scale model of a soil profile: A simple illustration that gives students an opportunity to take home their own microscale model of a real soil profile. It is possible to make this one as complex or simple as you desire. Consider using: Existing road cuts or stream banks on short field trips, 24 to 36" deep hole dug with a shovel in the school yard or lawn, a hole about 2 meters deep x 1 meter wide x 2 or 3 meters long dug by a backhoe, etc.
This activity uses math in developing the scale to represent the depth of the profile. (Paint sticks and glue work even better, if there is a place to let the glued soils dry.)
The direct url is http://soils.usda.gov/education/resources/k_12/lessons/profile/.
    Several other educational activities are included at the parent site: http://soils.usda.gov/education/resources/k_12/. The one above is included in the lessons link.
TEKS:
   Grade 3: 112.5.b3C, 11B
   Grade 4: 112.6.b3C
   Grade 5: 112.7.b3C
   Grade 6: 112.22.b3C, 4 A&B 		Tarrant soil profile
Scale model of soil particles: A medium-sized grain of sand (0.70 mm), just visible to the eye, is held in the calipers. (Click on the image for a larger picture, in which that is more easily seen. Click here for a close-up of the sand grain, which is just below the word sand between the black lines on the caliber jaws.)

If this barely visible object represents a clay particle (0.001 mm), then silt particles would be 1.4 to 35 mm in diameter, and sands would be 35 to 1400 mm in diameter.
So, the bb (4.4 mm), the large bead (9.0 mm), the small marble (14.3 mm), and the large marble (23.4 mm) would all be silt particles.
The golf ball (42.6 mm), the beach ball (~400 mm), and a ball with the diameter of the meter stick would be sands.
The standard screen in the background (about 1.8 m x 1.8 m) would be the size of a small piece of gravel.

Given the previous example, if a bb represents a clay particle (0.001 mm), how big would a sphere representing a silt (0.05 to 0.002 mm) or sand (2.0 to 0.05 mm) particle need to be?

(The largest sand particle would be a sphere 8.8 meters in diameter.)
 relative scale
relative scale
The Sponge Model: A sponge is used to represent several facets of soil water relations and engineering properties.
Water holding capacity of the soil.
Weigh a dry sponge. Soak the sponge. Hold the sponge above the water until all water drains. Weigh the wet sponge to determine the quantity of water the sponge holds against the pull of gravity. This represents the "field capacity" of soil. Squeeze all water possible out of the sponge. Weigh the sponge. The water removed from the sponge represents the "plant available water" in the soil. Let the sponge air dry and weigh it. Are the beginning and ending "dry" weights the same? Put the sponge in a drying oven (105 degrees centigrade or 230 degrees Fahrenheit for 24 hours). This represents the "dry weight" of soil (rather than the air dry weight). All soil water calculations are made relative to this dry weight. What is the percent of each water condition relative to the sponge dry weight.
Use a different sponge. Does it have the same characteristics?
The same process can be done with soils.
runoff from sponge
Soil is a filter: http://www.wtamu.edu/%7Ecrobinson/DrDirt/filter.html
Role of soil in the water cycle: Infiltration, filtration, and storage. Water moves into soil during precipitation events. The rate of water movement is determined by the soil texture and structure (shape of the aggregates, or clumps of soil particles joined together). Coarse soils and well-aggregated soils tend to have higher infiltration rates and better drainage of water through the soil and movement of air
into the soil (aeration). The soil filters pollutants physically, chemically, and biologically as water moves through the soil. If the system is not oveloaded, it functions well. Pollutants reach ground or surface waters when the soil is overloaded with a contaminant.
Water stored in soil can be used by plants, which transpire water back into the atmosphere. Some water stored by soil can be lost from bare soil surfaces by evaporation.
Math can be added by drying the soil prior to the experiment and adding the same weight of soil into each container, adding a measured quantity of water, recording the quantity of water collected in 15-second intervals (longer for some soils) to obtain a rate, recording the total quantity of water collected, and weighing the container to see if the quantity of water remaining in the soil matches the difference between the quantity added and collected.
TEKS:
   Grade 1: 112.3.b7A, 10 A-C
   Grade 2: 112.4.b7A, 10 A&B
   Grade 3: 112.5.b2 A-E, 3 A&C, 4 A&B, 7B, 11B
   Grade 4: 112.6.b2 A-E, 3 A&C, 4 A&B, 11A
   Grade 5: 112.7.b2 A-E, 3 A&C, 4 A&B, 6B
   Grade 6: 112.22.b2 A-E, 3 A&C, 4 A&B, 14B
   Grade 7: 112.23.b2 A-E, 3 A&C, 4 A&B (rate of water flow), 8A
   Grade 8: 112.24.b2 A-E, 3 A&C, 4 A&B, 8B, 12C, 14C
   Int Phys Chem: 112.42c2 A-D, 3 A&C, 4B, 9A
   Env Sys: 112.44c2 A-D, 5 B&F
   Chem 112.45c2 A-E
   Phys: 112.47c2 A-F
     (For concepts about water storage, see The Sponge Model: http://www.wtamu.edu/%7Ecrobinson/sponge/index.html.)
 filter set-up
soil is a filter
 
 Soil texture
Texture by feel and soil texture triangle: http://www.wtamu.edu/~crobinson/soils/unit_1/txtr_feel.html
   (sample image at right)

Use a bottle or jar to estimate the amount of sand, silt, and clay. This procedure integrates math with science. Measure the constituents of the bottle to estimate percentages by volume occupied.
Soil texture is determined from mass fractions. The activity by Ted Sammis also includes densities for an estimate of percentages by mass instead of volume.
          Background: https://www.soils.org/lessons/plans/lessons/texture.html
          Activity: https://www.soils.org/lessons/plans/activities/texture.html, Ted Sammis, NMSU
TEKS:
   Grade 1: 112.3.b2B
   Grade 2: 112.3.b4A, 2B, 4A
   Grade 3: 112.5.b4 A&B, 11B
   Grade 4: 112.6.b2 A-E (using different soil types), 4 A&B, 11A
   Grade 5: 112.7.b2 A-E (using different soil types), 4 A&B, 7B
   Grade 6: 112.22.b2 A-E (using different soil types), 4 A&B
   Grade 7: 112.23.b2 A-E (using different soil types), 4 A&B, 8A
   Grade 8: 112.24.b2 A-E, (using different soil types)3 A&C, 4 A&B
   Int Phys Chem: 112.42c2 A-D (using different soil types), 3 A&C, 4B, 7E
   Phys: 112.47c2 A-F (using different soil types) 		texture by feel
Add soil to bottle
 Add water to bottle
 Shake, then measure at 40 seconds
 24 hours later
soil in bottle
  soil + water in bottle
40 seconds - sand in bottom 
24 hrs later
Depth measurements for the bottles shown above.
   Total soil: 82 mm                         sand: 40 mm               silt: 62 mm               clay: 82 mm
   Determine the relative volume occupied by
         silt:  (silt - sand) = 62 mm - 40 mm = 22 mm
         clay: (clay - silt) = 82 mm - 62 mm = 20 mm
   Determine volume percentages of
         sand: 40/82 * 100 = 49%
         silt: 22/82 * 100 = 27%
         clay: 20/82 * 100 = 24%
         Using this volume estimation, the texture would be sandy clay loam.

Using the volume/mass density conversion (Sammis), multiply the percentage of sand by 1.19, the percentage of silt by 0.87 and the percentage of clay by 0.94.
   Determine the mass:
         sand: 49% * 1.19 = 58%
         silt: 27% * 0.87 = 23%
         clay: 24% * 0.94 = 22%
Sammis recommends letting the bottles sit for several days (allows more settling of the particles, especially the clays). This example shows why this is important. The sum of the sand, silt and clay is 103%. It cannot be more than 100%. Taking measurements after a few days should eliminate this problem.
         The texture from the mass estimates likely will be on the sandy loam/sandy clay loam line. 

Sand Castles: Pre-engineering 101
These simple exercises demonstrate some basic soil engineering properties using dry and wet sand (and other particles). Angle of repose of a material is determined by friction, gravity, adhesion and cohesion. In dry sand, gravity and friction dominate. Friction is affected by particle size and shape.
Use a funnel to pour a known weight of sand onto a blank sheet of paper. Draw a line around the circumference of the resulting cone. Measure the height and angle the material makes with the surface. Determine the height to diameter (width) ratio. Estimate the volume of the pyramidal cone. Do all materials have similar angles, ratios, volumes?

 small upright sandcastle
Soil Temperature
These exercises demonstrate the effects of water, color, mulch, and configuration on soil temperature.
Record initial temperature. Initiate the heat lamps, and record temperature at 5-minute intervals for 30-minutes (or longer - I use 1 hour), then remove the lamps and record temperature for another 30 minutes. Graph temperature (y-axis) versus time (x-axis). Evaluate the shape of the graph (linear or nonlinear) in both heating and cooling phases. Do all conditions behave the same?

 Bare and mulched soil under heat lamps
Other resources and opportunities:
Click on the links above to find the methods for each of the activities above. Visit Dr. Dirt's homepage to find other simple, educational activities suited for you classroom.  http://www.wtamu.edu/~crobinson/DrDirt.htm

Dig It! The Secrets of Soil Soils Exhibit in the Smithsonian Museum of Natural History
     http://forces.si.edu/soils/
     Information for teachers: https://www.soils.org/smithsonian/teachers.html
     Website for kids: https://www.soils.org/digdeeper/
Soil! Get the Inside Scoop Hey, I Want my Own Soils Book! That's what we said too! We made and wrote a book targeted for kids in Soil Inside Scoopgrades 4-6, with cool enough pictures that anyone of any age will love it! The book talks about how "Soil is NOT Dirt" and "Yikes, It's Alive!" It comes with your very own soils glossary and lots of pictures to explain soil and show pretty, colorful soils from all over the world! It's now available for purchase SSSA's online bookstore (note, you'll need to create an account or login to purchase).



Window on a Wider World: http://www.windowonawiderworld.org/
      Look for a STEM (Science, Technology, Engineering and Mathematics) Collaborative in February, focused on Earth and Energy
      Erosion and other topics will help provide teachers activities to help students master middle school science TEKS

Panhandle Math-Science Teachers' Conference, September 20, 2008, West Texas A&M University, Canyon, TX
In June, conference information will be accessible from the conference’s website at www.wtamu.edu/pmsc.
If you have any questions, please contact us at 806-651-2906 or acampbell@wtamu.edu .
Dr. Ashley Campbell                                      Mr. Gilbert Antunez
Conference Co-Chair                                     Conference Co-Chair

National Science Teachers' Association: http://www.nsta.org/

Clay Robinson, Ph.D., alias Dr. Dirt
Professor of Soil Science
West Texas A&M University
http://www.wtamu.edu/~crobinson/DrDirt.htm
crobinson@wtamu.edu
office phone: 806.651.2553
fax: 806.651.2938