Does a slinky move up and down equally?

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When a slinky is pulled down and released, the distance it moves down may not equal the distance it moves back up due to factors like oscillation modes and the non-linear properties of the slinky. The discussion emphasizes the importance of defining the reference point, such as the equilibrium position or the center of mass. If the slinky is pulled down 10 centimeters, it may not necessarily return to the same height, especially if it experiences different forces during oscillation. The potential for the slinky to bounce indefinitely is contingent on the balance of forces and energy involved. Ultimately, the distances moved in each direction can vary based on the initial conditions and the slinky's characteristics.
Bagwan
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Let's say there is a slinky being held up. If I pull the bottom of the slinky, it will keep oscillating/vibrating/swinging up and down continuously, until it comes to a stop.

My question is, is the distance the slinky moves down the first time EQUAL to the distance it moves back upwards?

Or is one distance larger than the other?

Thank you very much in advance.
 
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This depends on your exact initial conditions and what you mean by equal distance (the center of mass displacement from its equilibrium or perhaps the endpoint position).
 
The reference point I'm talking about is the equilibrium, sorry I didn't mention that! At first, the slinky would be at its rest position, then pulled slightly to the bottom.
 
You need to specify exactly how it is pulled (is it pulled down and released from rest, is it just given some momentum, etc).

What do you mean with resprct to the equilibrium? The position of the end? The position of the center of mass of the slinky? Something else?

Regardless of the setup, the answer is likely that it is not going to go up and down equally as you are likely to excite more than one oscillation mode.
 
Purely theoretically, if I were to allow a hanging slinky to reach its resting position (that is, the location where the slinky doesn't move at all while hanging), and then my hand pulled the bottom of the slinky downwards towards the ground slightly (perhaps 10 centimeters below the resting position), if there were a magical ruler that measured the distance it pushed back upwards from the resting position, would that also be 10 centimeters?
 
If it wasn't less, it would keep bouncing indefinitely.
 
Yeah you're right about that, but I was just thinking that they both could be equal, and then in the next oscillation both distances could go down by the same amount. That would still lead it to stopping, right?
 
Now in the other direction would be a different story, if you lifted the end of the coil 10 cm and let it accelerate towards the ground it might travel further depending on its elasticity versus mass.
 
jerromyjon said:
If it wasn't less, it would keep bouncing indefinitely.
He isn't asking about more extension after a full cycle, just after half the cycle. Why shouldn't a non-linear spring, go higher above the equilibrium than it was pulled below it?
 

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