Underwater Fireworks

Fireworks are fabulous! We love watching the colors explode and gently float down through the air, but we can’t watch fireworks all the time. Underwater fireworks are something we can watch any time, even in our kitchen!

The Experiment

Supplies: Water, vegetable oil, food coloring (any color), a large clear glass, a second smaller glass, a fork

What to do: Fill the large glass almost to the top with room-temperature water. Pour 2 tablespoons of oil into the other glass. Add 2 drops of food coloring to the glass with the oil. Vigorously stir the oil into the food coloring using a fork. Stop once you break the food coloring into little drops. Pour the oil and coloring mixture into the tall glass. Now watch! The food coloring will slowly sink in the glass, with each droplet expanding outwards as it falls.

What is happening: Food coloring dissolves in water, but not in oil. This has to do with the incompatibility of the molecular structures of the water and the oil. When you pour in the food coloring/oil mixture, the oil will float at the top of the water because it is less dense. The food coloring will begin to dissolve once it sinks through the oil and into the water.

Take It Further

Variations on this demonstration:

  • Try mixing in one drop each of two different food colorings.
  • What happens if you omit the oil and drop the food coloring directly into the water?
  • Try varying the size or shape of the water glass, the amount of the oil, or the amount of the food coloring. Just remember, when you are manipulating variables to only change one thing at a time!

Links

For a more detailed explanation of the miscibility of fluids, along with a more expansive version of this demonstration, head over to the Scientific American website.

Exploring Density

Density describes the relationship between a substance’s mass, or weight, and its volume, or how much space it takes up. Things that are more dense take up less space than things with less density. To visualize density, let’s compare baseballs and marshmallows. A regular baseball weighs about one pound. It is small and compact and fits in the palm of your hand. A 16 oz. bag of marshmallows also weighs one pound, but because there is more air incorporated into the marshmallows, they are less dense. One pound of marshmallows takes up a lot more space, or volume, than a one-pound baseball.

When you combine substances that have different densities, the substances with the greatest density tend to move toward the bottom, while those with lesser densities tend to rise to the top. Gases tend to be lighter and less dense than liquids. Liquids tend to be lighter and less dense than solids. Even within these groups, there are a variety of densities.

The Experiments

Simple Experiment

Supplies: A clear jar with a lid, vegetable oil, water, food coloring (optional).

What to do: Fill the jar about half-full with water. Add food coloring, if desired. Pour in vegetable oil until the jar is almost full. Put the lid on the jar and MAKE SURE IT IS TIGHT. Give the jar a good shake so that the water and oil are thoroughly mixed. Set the jar where it won’t be disturbed and observe the liquid.

What is happening: The oil is less dense than the water, so it rises up to “float” on the surface of the water. The water and oil do not mix because of the molecular properties of each compound. Water molecules tend to want to “stick” to other water molecules, while oil molecules tend to want to stick to other oil molecules. This is because of something called molecular polarity, where the structures of the two molecules are not compatible. They push each other away, similar to a pair of magnets that won’t stick together. The longer the jar sits, the more the water and oil will sort themselves out, until they are completely separate again.

Complex Experiment

Supplies: A large jar or clear glass cylinder, liquid measuring cup with pour spout, a turkey baster, different colors of food coloring, honey or molasses, light corn syrup (Kayro), blue liquid dish soap, rubbing alcohol, yellow corn oil, water.

What to do: Pour 1 cup of honey or molasses into the bottom of your jar. Measure out 1 cup of light corn syrup and add some red food coloring. Stir until well combined. Carefully pour the corn syrup into the jar, making sure to avoid hitting the sides of the jar. Measure out 1 cup of dish soap. Slowly add the dish soap, again avoiding the sides of the jar. Measure out 1 cup of water and add to the jar, but this time use the turkey baster to slowly drizzle the water down the side of the jar. Measure out 1 cup of corn oil and add to the jar, again using the turkey baster. Finally, measure out 1 cup of rubbing alcohol. Add green food coloring and stir well. Add the rubbing alcohol into the jar using the turkey baster.

What is happening: Different liquids have different densities. Liquids like honey and dish soap are more dense than water, while other liquids, like rubbing alcohol and vegetable oil are less dense and will float above the water. Adding the food coloring helps distinguish the different layers. The various densities of the different liquids is what keeps the layers separate.

Links

You could take the Density Column experiment one step further by dropping in solid objects to see where they land, OR you could just watch this great video from the Bearded Science Guy.

Find the Invisible Space

Matter is what scientists call all the stuff around us. Matter may come in all different colors, shapes, and sizes, but all matter can be “broken down” into smaller parts – all the way to the atomic level. At its core, matter is just a bunch of different atoms that have gotten together in an organized fashion. Atoms are the core building blocks of everything around us.

Atoms are super tiny, so small that they can only be seen with a special kind of microscope. Atoms have a center, called a nucleus, which contains parts called protons and neutrons, and they have things called electrons that float around the outside of the nucleus, sort of like how the moon “floats” around the Earth. Every atom has some “invisible space” that exists between the nucleus and the electrons.

Think of a bin filled with loose LEGO. Each individual piece represents an atom. When you put two or more atoms together, you create a molecule. Different molecules have different shapes and sizes. When you put multiple molecules together, you get a compound. Compounds can be combined to make anything, just like LEGO bricks, but regardless of what you build, the invisible space still exists at the atomic level.

Even though we can’t see the invisible space, we can still prove that it exists using everyday objects.

The Experiment

Supplies: A 1 cup measuring cup, a measuring cup that is at least 2 cups, water, and rubbing alcohol.

What to do: Measure EXACTLY 1 cup of water very carefully and pour it into the large measuring cup. Measure EXACTLY 1 cup of rubbing alcohol and pour the rubbing alcohol into the large measuring cup. Check the amount of liquid in your large measuring cup. Is it 2 cups of liquid?

What is happening: Water molecules consist of a single oxygen atom combined with two hydrogen atoms. Rubbing alcohol molecules have three carbon atoms, seven hydrogen atoms, and a single oxygen atom. The shape of the rubbing alcohol molecules allows them to “slide” in-between the water molecules and fill the invisible spaces. This is one case where 1 + 1 does NOT equal 2!

Links

To learn more about atoms, check out Rader’s Chem4Kids website.