Explanation for this interesting rotational effect?

andresB · Jun 10, 2019

You can see the effect around minute 1:20 in this video. It seems to me that the un-twist of the elastic band and the rotation of the ball about the line that joins them is what keep the constant the initial zero angular momentum, though I can't tell for sure.

The inversion of in the direction of rotation somewhat reminds me of Dzhanibekov effect, though most likely not related at all.

A.T. · Jun 10, 2019

andresB said:

An effect that seemingly goes against the law of conservation of angular momentum.

Why should angular momentum be conserved in a non-isolated system?

andresB · Jun 10, 2019

A.T. said:

Why should angular momentum be conserved in a non-isolated system?

Are you saying that the reverse of the rotations comes from the interaction of the balls with the table?

A.T. · Jun 11, 2019

andresB said:

Are you saying that the reverse of the rotations comes from the interaction of the balls with the table?

Why just the reverse? How do you think the balls start moving in the first place, after being released?

rcgldr · Jun 11, 2019

A.T. said:

Why should angular momentum be conserved in a non-isolated system?

To clarify A. T.'s post, the balls exert a torque onto the surface, so to be a closed system, you'd have to include the surface and whatever the surface is attached to (like the earth).

andresB · Jun 11, 2019

A.T. said:

Why just the reverse? How do you think the balls start moving in the first place, after being released?

That makes sense.

Explanation for this interesting rotational effect?

1. What is the cause of this rotational effect?

2. How does this rotational effect occur?

3. Can this rotational effect be seen in other systems besides objects in motion?

4. Is there a mathematical formula for calculating this rotational effect?

5. How is this rotational effect used in everyday life?

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