We will try to see if a slinky spring could provide us clues about how sound travels. Consider a slinky spring kept on a table. We can compress it by giving it a sudden jerk from one side.
Watch the slow motion video given below. You can also try it out in your classroom.
Video 4.2 (a): A single compression traveling along a slinky
Now let us move our hand back and forth.
Video 4.2 (b): Many compressions and rarefactions traveling along a slinky
You can see that there are alternate regions where the slinky spring is compressed and where it is elongated. The diaphragm of a speaker also moves back and forth. It compresses the air when it moves forward and makes the air rarer/sparser/less dense when it moves back. Just as these successive compressions and rarefactions that travel along the slinky, sound travels away from a speaker through air. Sound travels in the same way through liquids and solids too.
[Contributed by administrator on 25. Juli 2024 01:51:20]
Slinky spring
We will try to see if a slinky spring could provide us clues about how sound travels. Consider a slinky spring kept on a table. We can compress it by giving it a sudden jerk from one side.
Watch the slow motion video given below. You can also try it out in your classroom.
Video 4.2 (a): A single compression traveling along a slinky
Now let us move our hand back and forth.
Video 4.2 (b): Many compressions and rarefactions traveling along a slinky
You can see that there are alternate regions where the slinky spring is compressed and where it is elongated. The diaphragm of a speaker also moves back and forth. It compresses the air when it moves forward and makes the air rarer/sparser/less dense when it moves back. Just as these successive compressions and rarefactions that travel along the slinky, sound travels away from a speaker through air. Sound travels in the same way through liquids and solids too.