Science Experiments You Can Do at Home

Here are some fun Weird Science experiments you can reproduce at home! Most of these are adapted from Steve Spangler Science©. Because Steve is a Science Education Correspondent for Denver’s Channel 9 News, you can watch some of his fun videos on their website (http://www.9news.com/news/education/spangler/default.aspx)

Can you skewer a balloon without popping it?

Materials needed:

1 or more balloons

1 barbeque skewer

a little vegetable oil (any kind will work)

What to do:

1. Blow up a balloon and tie the end.
2. Dip the sharp end of the barbeque skewer in vegetable oil.
3. Look for the “darker spots” of the balloon, or places where the latex molecules are more dense (hint: the top and bottom of the balloon is a good place to start looking).
4. Slowly and tenderly pierce the skewer through a dark spot of the balloon. Then guide it all the way through the middle of the balloon until you reach another dark spot on the other side. Gingerly pierce the other side and…

Voila! You’ve skewered a balloon! 

The science behind it:

The latex molecules that make up the balloon are the least stressed near the top and bottom of the balloon, whereas they are the most stressed (stretched out) along the sides of the balloon. At the ends of the balloons where the molecules aren’t as stretched out, these long molecular chains wrap themselves around the place where you inserted the skewer, consequently keeping the air from escaping the balloon.

Fireworks on a plate!

Materials needed:

3 plates

1 cup of whole milk

1 cup of 1% milk

1 cup of water

food coloring (several colors are best)

Dawn soap

1 or 2 Q-tips

What to do:

1. Cover the first plate with whole milk.
2. Cover the second plate with 1% milk.
3. Cover the third plate with water.
4. Put several drops of food coloring (different colors) in each liquid, in the center of each plate. Be careful not to stir them.
5. Dip one end of a Q-tip in Dawn soap, then dip the same end in the center of the plate with the water and food coloring. What happens? Watch it for a minute or so.
6. Dip a Q-tip in the soap again. Then dip it in the center of the plate with the 1% milk. What happens this time? Again, watch for a minute. Does the food coloring move around more than it did in the water?
7. Finally, dip the Q-tip in soap one more time. Now dip it in the center of the plate with the whole milk. Watch the food coloring for a while. How long does it move around the plate compared to the water and 1% milk?

The science behind it:

Soap is a bipolar molecule. This means that one end of the molecule is polar, and one end is non-polar. The polar end is attracted to water, while the non-polar end is attracted to the fat in the milk. The soap therefore weakens the bonds that keep the fats and proteins in the milk solution. The food coloring is just a “tracer” that allows you to watch it happening!

Upside-down water!

Materials needed:

1 ball jar, with ring that goes around the lid

1 piece of screen (window screen, shade cloth, or similar; large enough to cover top of jar)

1 piece of card stock or similar paper

Water

What to do:

1. Take the lid off the ball jar and place the screen over the top.
2. Screw the ring on the jar to hold the screen in place.
3. Fill the jar to half or ¾ full with water.
4. Place a piece of card stock over the top, so that it completely covers the screen.
5. Holding the cardstock securely in place, turn the jar upside down (over the sink or outside is best!).
6. Ask your child to hypothesize what will happen when you remove the cardstock.
7. Slowly remove the cardstock by sliding it off to the side and then away from the jar.
8. Keep the jar stead and perfectly vertical for this to work!

The science behind it:

The water stays in the jar because of surface tension. Water molecules stick together because of a force called cohesion. This force causes the water molecules to essentially “glue” themselves together between openings in the screen, and this surface-tension “membrane” that is formed is what holds the water in the jar. It is also the reason why raindrops are spherical.