WRITE THE PROCESS OF MAKING SOLAR ECLIPSE EXPERIMENT
Answers
Materials:
Small apple
Large handful of clay
Two pencils
Notebook
Pencil
Lamp
Procedure
In this experiment, you’ll use an apple as the sun. Place the bottom of the pencil through the base of the apple so that the apple sits on the stick.
You’ll use a small ball of clay as the moon. Roll a ball of clay that’s about an inch in diameter and stick it on top of the other pencil. Make sure that both your moon and your sun are well secured on top of the pencils.
Now, place the “sun” pencil into a pile of clay in the middle of a table. Make sure it stands upright. Make sure you’re about eye-level with the apple, and hold the “moon” pencil in your dominant hand.
Close one eye.
Move your “moon” pencil from the right of your field of vision until it’s in front of your open eye. Now stop the pencil. Does the moon appear to cover the sun? If so, you’re witnessing a total eclipse.
Now, move the moon pencil forward toward the sun. Does the moon look bigger or smaller? Does it cover more or less of the sun? Move the pencil back toward your open eye. Does the moon look bigger or smaller? Does it cover more or less of the sun?
Next, move the moon pencil until it covers all but the very edges of the sun. This is an annular eclipse, and when it happens in real life, you can see a bright ring around the edges of the sun known as the photosphere.
Place a lamp behind your apple sun.
Give your moon to a friend and watch her move it in front of her eyes. Watch how the shadow changes on your friend’s face. The middle, darker part of the shadow is called the umbra. The lighter part of the shadow around the umbra’s edge is called the penumbra. During a real eclipse, the sun and moon will look different depending on whether you’re standing under the moon’s umbra or penumbra.
Make notes about your observations. And yes—you can eat the apple now too!
Results:
As the clay ball (moon) moves closer to your eye, it looks bigger and blocks out more of the larger ball (sun).
Why?
An eclipse happens when something in the sky (in this case, the moon) passes between the earth and the sun, covering the light from the sun. When an eclipse involves the moon, the moon doesn’t get bigger—it only appears to be larger.
Imagine that you see two friends walking down a road. One friend is a block away. The other friend is a few steps in front of you. Your friends are roughly the same height. Which one would look larger? The friend who is a block away looks smaller because he is farther away, and the friend standing close by looks larger, even though he is the same size.
Now, let’s pretend that the friend who’s far away is much bigger than the friend who’s standing a few steps in front of you. Who would look larger now? Yes, it would still be the friend who’s standing in front of you!
This phenomenon is called apparent size, and it happens because the light hitting your eye hits it at a smaller angle when an object is farther away. A 6-foot tall person standing 8 feet away from you looks like he is around the same size as a 3-foot tall person standing 4 feet away from you.
Think of that tall person as being a lot like the sun, which is very away from the earth (about 93 million miles away, to be precise!). The moon, on the other hand, is only 238,900 miles away. Since the moon is so much closer to us, it looks like it covers the sun, even though the sun is far larger