Take a slinky as shown below.
Ask a friend to hold one of its ends. You hold the other end and move away from your friend. Now you release the slinky.

What happened?

Take a slinky as shown below. Ask a friend to hold one of its ends. You hold the other end and move away from your friend. Now you release the slinky. How did the slinky acquire energy when stretched?

Take a slinky as shown below. Ask a friend to hold one of its ends. You hold the other end and move away from your friend. Now you release the slinky. How did the slinky acquire energy when stretched?

Take a slinky as shown below. Ask a friend to hold one of its ends. You hold the other end and move away from your friend. Now you release the slinky. Would the slinky acquire energy when it is compressed?

Take a slinky as shown below. Ask a friend to hold one of its ends. You hold the other end and move away from your friend. Now you release the slinky. Would the slinky acquire energy when it is compressed?

Take a slinky Ask your friend to hold one end.you hold the other end.Now stretch the slinky as shown in fig(a) .Then give it a push towards your friend as shown in fig (b) If you move your hand pushing and pulling the slinky alternately .What will you observe?

Take a piece of thread and tie a small place of stone at one of its ends. Hold the other end of the thread and move the stone to describe a circular path with constant speed. A stone describing a circular path with a velocity of constant magnitude Now, release the thread. Can you tell the direction in which the stone moves after it is released ?

Take a piece of thread and tie a small place of stone at one of its ends. Hold the other end of the thread and move the stone to describe a circular path with constant speed. A stone describing a circular path with a velocity of constant magnitude Now, release the thread. Can you tell the direction in which the stone moves after it is released ?

Take an empty bottle of the sort in which bottled water is sold. Pour about 5-10 mL of water into it and close the bottle tightly. Shake it well or leave it out in the sun for ten minutes. This causes the air in the bottle to be saturated with water vapour. Now, take a lighted incense stick. Open the cap of the bottle and allow some of the smoke from the incense sticks to enter the bottle. Quickly close the bottle once more. Make sure that the cap is fitting tightly. Press the bottle hard between your hands and crush it as much as possible. Wait for a few seconds and release the bottle. Again press the bottle as hard as you can. Now answer the following questions : What might happen you do the experiment without the smoke from the incense stick? Now try it and check if the prediction was correct. What might be happening in the above experiment in the absence of smoke particles?

Take an empty bottle of the sort in which bottled water is sold. Pour about 5-10 mL of water into it and close the bottle tightly. Shake it well or leave it out in the sun for ten minutes. This causes the air in the bottle to be saturated with water vapour. Now, take a lighted incense stick. Open the cap of the bottle and allow some of the smoke from the incense sticks to enter the bottle. Quickly close the bottle once more. Make sure that the cap is fitting tightly. Press the bottle hard between your hands and crush it as much as possible. Wait for a few seconds and release the bottle. Again press the bottle as hard as you can. Now answer the following questions : What is the need for smoke particles inside the bottle for this experiment ?

Cut a right angled triangle, stick a string along its perpendicular side, as shown in fig. (i) hold the both the sides of a string with your hands and rotate it with constant speed. What fo you observe?