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Water-wise: Keep Soil Wet Without Waste


Key Concepts
Water-holding capacity, soil types
Sabine De Brabandere, PhD, Science Buddies
Rice flour, popcorn kernels, and corn meal in three separate coffee filters over glass cups.


It is almost mid-summer! You might have colorful flowers, fresh tomatoes and yummy berries in the garden. But wait, did you remember to water them?  Maybe you wonder if they get enough, too much or too little water. Should you water every day, twice a day or once a week? Should you soak the ground, or is frequently providing small amounts of water better? Unfortunately, there is no general rule, because much depends on the type of soil. In this science project, you will see how much water soil can hold, by practicing not with dirt, but with readily available kitchen substitutes. Once you understand some general principles, you should be better equipped to tackle the real problem of watering wisely.

This activity is not recommended for use as a science fair project. Good science fair projects have a stronger focus on controlling variables, taking accurate measurements, and analyzing data. To find a science fair project that is just right for you, browse our library of over 1,200 Science Fair Project Ideas or use the Topic Selection Wizard to get a personalized project recommendation.


Some experts claim U.S. residents waste billions of gallons of water in outdoor use each day. Watering gardens is one contributor. Why is it so difficult to water the garden wisely?

Ideal watering schedules (how much and how frequently you should water) depend largely on how much water the soil can hold. If the soil cannot hold onto water, a frequent, smaller amount of water is needed. For a soil that can hold onto water, a less frequent substantial watering schedule is better.

Two factors play a major role in determining the water-holding capacity of soil: the structure of the soil – or how big or small the particles in the soil are – and the amount of organic material present in the soil. Organic material refers to broken-down plant and animal material. Water loves to cling to organic material, so more of it mixed in the soil allows the soil to hold onto more water. In terms of soil structure, smaller particles have more surface area for the same volume of soil, meaning more area for water to stick to. This activity will verify this with insoluble dry food. Will grinding up the food allow the same volume of substance to hold more water? Once you have put your “soil” to the test, read the conclusion and check out the links in the “more to explore” to see how you can apply this to the soil in your garden.


  • Paper towels or kitchen towels to protect your workspace in case of spills
  • Four identical glasses; preferably glasses with a rather narrow opening so the cone-shaped coffee filters can rest in the glass opening
  • Three clean cone-shaped paper coffee filters
  • 2/3 cup dried rice, rice meal (or coarsely ground rice) and rice flour (or finely ground rice) Alternatively, you can use dried corn kernels, cornmeal, and corn flour, or grain berries, bulgur and wheat flour
  • 1/3 cup measuring cup
  • A helper
  • Water
  • Workspace that can tolerate some liquid splashes
  • Optional: Plastic coffee filter cone(s), which can hold your paper filters and help prevent spills
  • Optional: Kitchen scale


  1. Protect your workspace with some paper towels or a kitchen towel
  2. Open a coffee filter and let it rest in the opening of a glass. Repeat with two other filters and glasses. You will have one glass left.
  3. If you have coffee filter holders available, use them, especially for the dried rice. They will help prevent spills. .
  4. Put 2/3 cup of dried rice in the first filter.
  5. Put 2/3 cup of rice meal in the second filter.
  6. Put 2/3 cup of rice flour in the last filter.


  1. If you have a kitchen scale available, weigh the filters with the dry substances, one at a time. Write down your measurements.
  2. Look at the three substances: dried rice, rice meal and rice flour. How are they similar and how are they different?
  3. In a moment, you will pour water over these substances. Which one do you think can hold more water? How could you measure how much water it can hold?
  4. Pour 1/3 cup of water over the dried rice. Before you do so, ask a helper to hold the filter up so it does not flip over and spill. If you have a coffee filter holder, this will do the job as well.
  5. Repeat the previous step, now pouring 1/3 cup of water over the rice meal and then over the rice flour. Observe what happens. Does water seep through the substances? Why does this happen?
  6. Water gets pulled down by gravity. In the three setups, the water does not change, gravity does not change, so why does it not seep through in the same way in the three cases?
  7. Pour another 1/3 cup of water over each substance. Be careful, the filter might flip. Do you think more or less water will seep through this time?
  8. Fill the last glass with 2/3 cup of water and place it next to the other glasses. How could this glass help you discover which substance can hold the most water?
  9. After about 5 minutes, compare how much water ran through the substances in the glasses. Your fourth glass shows you how much water you poured over the substances. Which glass has the most water? If there is less water in some glasses, where has the water gone?
  10. If you have a kitchen scale, weigh each filter with its wet substance. Are the measurements different from the mass of the dry materials measured in the first step? Which samples gained the most mass? Where is this extra mass coming from?

Extra: If you have compost available, you can measure how adding compost influences the water-holding capacity of soil. For example, you could create a 1:2 compost-rice meal mixture by adding one scoop of compost for each two scoops of rice meal and compare the water-holding capacity of this mixture to that of pure rice meal using the method described in this activity.

Extra: Can you measure how much water the dirt in your garden or flower pot can hold? Take a sample of dry dirt from the garden or the flower pot. If the dirt is wet, you will need to let it dry out before you do the test. Crumble the dirt so it is loose and grainy and perform the test from this activity. How much water can 2/3 cups of dirt hold? What would happen if, during a watering cycle, you add more water to this dirt? Should you let the dirt dry out completely before re-watering?  How could that influence your watering schedule?  

Extra: Geologists classify soils in three main types: sand, silt, and clay. Clay has the smallest particles; you might need a microscope to see them. Next comes silt, and then sand. Which type of soil do you expect to hold water best? If you can find small samples of these types of soil, repeat the experiment with them to test your prediction.

Observations and Results

Was the dried rice barely able to hold water, while the smallest grind retained the most water?  This is what is expected.

Water runs down because it is being pulled on by gravity. Water needs a surface to cling to in order to overcome gravity and stay in the sample. The more you grind a substance, the smaller the particles in the substances are, and the more total surface there is for water to hold onto.

Soils differ, not only in particle size, but also in consistency (or what they are made up of). Still, particle size plays an important role in determining how much water the soil can hold. Sandy soil has larger particle size; it cannot hold much water and needs frequent smaller doses of water.  Silt has smaller particles; its water-holding capacity is ideal for most plants. Clay has tiny particles, so it might hold too much water, causing plants to rot.

Adding organic material (broken-down plant and animal material) to soil does not only increase the nutrient content of soil, but it also improves the water-holding capacity of the soil. 

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  1. Your samples and filters can go into the compost bin. Water your plants with the leftover water.

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