Science Magic?

These were collected from various sites on the web, including:

Beakman’s World http://www.geocities.com/TelevisionCity/Set/4567/ex.html and

Bizarre Stuff to Make in Your Kitchen http://home.houston.rr.com/molerat

Egg in a bottle

There are plenty of other dumb things to do with eggs, one being the egg in the bottle trick. Use a shelled, hard-boiled egg. The egg needs to be free from cracks in the white and smooth. Find a bottle with a neck just small enough that the egg won't fall in (a carafe, milk bottle, or some baby bottles). Wad up a little piece of paper and drop it in the bottle (you can also use 2 or 3 wooden matches). Light the paper or matches, allow to burn out, and immediately put the egg in the bottleneck, where it should be sucked in (making a very interesting sound in the process). Actually, the egg isn't sucked in, it's pushed. The fire heats the air, causing it to become less dense and to rise out of the bottle. This causes a decrease in air pressure inside the bottle. The higher pressure outside the bottle pushes the egg in.

A reader recently reminded me that you can easily get the egg out again by turning the bottle upside down and blowing into it very hard. When you take your mouth away, the egg should pop out due to the increased air pressure in the bottle.

Floating egg

A raw egg can also be made to float in very salty water. If you can half fill a glass with salt water, and top it off with fresh water without letting the two mix (pouring the water over the back of a spoon helps), you should be able to gently lower an egg into the glass and suspend it between the layers. It looks pretty cool especially if you don't know how it was done. It is also possible to mix a solution of salt water, through trial and error, that matches the specific gravity of the egg. The egg will float at whatever level it is placed in the jar. When a little salt is added, it will float to the top. If a little fresh water is added, it will sink.

The floating sugar cube trick

You can make a "trick" sugar cube that will sink in a cup of hot liquid, then float without dissolving. You will need some collodion, which, conveniently enough, is the main ingredient of New Skin, which is used to cover blisters. Pour some New Skin in a small cup. Dunk the sugar cube in the New Skin, making certain that it is completely immersed, and hold it there for 20-30 seconds. It is easiest to do this using tweezers. Remove it and set it aside to dry for one full day.

The collodion has covered all of the sugar crystals. When the cube is dropped into hot water (or tea), eventually the sugar melts, leaving the collodion "skeleton" behind, which floats. Do not, of course, eat the collodion treated cube.

Clouds in a bottle

This simple classic forms a little cloud in a bottle. You will need a large glass jar with a wide mouth, such as an industrial size pickle jar; a sheet of rubber (a balloon that has been slit open); a rubber band large enough to fit over the mouth of the jar; some chalk dust (or talcum powder); and some cold water.

Wash out the jar and put about an inch (25mm) of water in the bottom. Cover the mouth of the jar with the piece of rubber and cover with a book to hold it in place. After 10-15 minutes, remove the book and rubber from the jar. Drop in a spoonful of chalk dust or talcum and quickly replace the rubber over the mouth. Wrap the rubber band tightly around the rim to keep the rubber sheet firmly in place over the mouth. Push down on the rubber with your fist until it is depressed a little way into the jar. The air is compressed and warmed, so it is able to hold more water vapor. After 15 seconds or so, quickly remove your fist. The air will cool, and will not be able to hold as much water vapor. This excess vapor condenses around the chalk dust, forming a cloud inside the jar.

You can do the same thing with a jar or large bottle and a cork The cork needs to make a good seal, so give it a good soaking if it is dry. Put a little cold water in the jar. Cork the jar, and let it stand for 15 minutes or so. Remove the cork, quickly pour in a little talcum powder or chalk dust, and re-cork. Push the cork farther into the jar. This increases the air pressure, warming the air inside. After 15 seconds or so, pull the cork a little bit of the way out (but not all the way - you need to keep the seal). The pressure drops, the air cools, and the excess water vapor condenses on the tiny particles of powder in the air.

Sound rings

Under certain conditions, short bursts of sound will set up peculiar vibrations in the air known as "sound rings". These rings carry a lot of power with them. Some have been produced that will knock over relatively large objects at several meters away!
You can create small versions of these that will blow out a candle. Use a round cardboard box, such as an empty oatmeal box. Cut a round hole the size of a penny (U.S. - 37mm) exactly in the center of the lid. The hole should be as perfectly round and smooth as you can get it. Tape the lid tightly on the box.
Point the hole in the box top at a candle flame three feet (one meter) away. Sharply tap the bottom of the box. Sound rings should form which should be strong enough to put out the candle. By trial and error you can determine how far the box can be from the candle and still put it out. You may be able to get 6 feet (2 meters) or so away.
You can make the rings visible by adding smoke. Do this outdoors, or at least someplace well ventilated. Remove the lid, light a damp paper towel so it just smolders, hold the paper towel in the box to fill it with smoke, and seal the lid back on. Make sure you have a safe place to put the smoldering paper towel when you are done with it! When you tap on the box, you should be able to see the smoke carried by the sound rings.

You can also make a sound ring generator with a plastic soda bottle and a toy balloon. Cut off the bottom of the empty bottle as evenly as possible. Sand it smooth, or heat it so that it can be smoothed. Cut the balloon so that you have a piece of rubber large enough to cover the hole in the bottom of the bottle. Tape it into place. Duct tape works well for this. The balloon should be fairly taught. Grab the balloon in the middle and pop it. This will give a fairly strong little burst.

Ryan Hersh writes to add the following design suggestions:

Both ends of a tin can are removed. A toy balloon is attached to one end and a piece of cardboard with a hole at the other.
A larger one can be made from a plastic trash can with a flat lid.
10-gallon buckets that detergent/paint/some bulk foods come in also work well.

I challenge you to get the queen of hearts to make the water stay in this glass when we turn this glass over. Think you can do it?

Here's what you'll need for this experiment:

1. an ordinary drinking glass.

2. The Queen of Hearts from an ordinary deck of cards (actually any card from the deck will do.)

Now, you'll want to perform this experiment over a sink to ensure that we don't get the floor soaked.

Here's how you do it:

1. Fill the drinking glass half way with water.

2. Place the queen of hearts over the top of the drinking glass making sure that the card covers the entirety of the mouth of the glass.

3. While applying pressure on the card gently turn the glass over. once the glass is completely turned over remove your hand from the card. ZALOOM! The card should now be held in place under the mouth of the glass without any assistance from you, without the water rushing out of the glass.

What's the gimmick you ask?! Well, it's a little thing I like to call air pressure. And it goes a something like this:

You know how when you go down to the bottom of a swimming pool you can feel all that water pushing in on you? Well, even though you can't see it, we live at the bottom of an ocean of air that's always pushing in on us. The air around the card actually pushes up against the card harder than the water pushes down on the card. In fact, you would need a glass of water almost 30 feet high before the water would weigh enough to push the card off the glass.

Make An Oscilloscope
(Pronounced "Ah-sil-lo-scope")

An oscilloscope is an instrument used to see patterns of sounds as well as hear them. Students can see the vibrations their voices make by building their own oscilloscopes.

Grade Level: Elementary

Materials

Balloon
Masking tape
Glue
Very small mirror
Flashlight
Small steel can (like V-8 can)
Plain white card
An inquiring mind

Discussion

From motorcycles to motion pictures, engineers make motors hum and soundtracks sing. They have helped invent ways to record sounds as well as ways to get rid of noise where you might live. Think of the highway walls that keep traffic sounds out of quiet neighborhoods.

Sound comes from patterns or waves of vibrations in the air which, in turn vibrate in your ear, which is how you hear. (Notice which word is in the word hear). An oscilloscope lets you see sounds.

Activity

Remind students that any time they perform activities such as these, an adult should be present. For this activity, students can work in teams, with one set of materials for each. In advance of your school visit, remove both ends of the cans. Have the students:

1.Stretch a balloon piece tightly over one end and secure it with masking tape.

2. Attach the mirror to the balloon with a small amount of glue. Don't put the mirror in the middle of the balloon. It won't work as well.

3. Dim the lights then shine the flashlight so that it reflects off the mirror. Hold a plain white card so the the light reflects off the mirror and onto the card.

4. Next have someone speak into the can. The reflection will vibrate as he/she talks.

Questions for students

What sorts of vibrations do different voices make?
Why might engineers and scientists want to study sound waves?
How can you stop sound from traveling?

I defy you to push this plunger handle through this tissue. You say that's no challenge. You say you've been known to push a sneeze through a tissue?

Pencil Alert !

you'll need:

1. A tissue

2. A plunger

3. A paper towel tube

4. a rubber band

5. A bunch of salt

You need to secure the tissue around one end of the paper towel tube with the rubber band. Take your salt and pour it in a depth of at least 6 inches into the tube. Now it's plunger time! No, no not the business end, use the handle please. Put the handle into the tube and try your best to push through the tissue. Couldn't do it could you?!!

What happened why didn't that work?!!

You see there are lots and lots of tiny air spaces between the grains of salt. When the plunger strikes the energy from the blow goes into pushing the salt crystals closer together and against the sides of the tubes. There is no energy left to tear the tissue.