What is the Angular Momentum of a Rotating Disk?

AI Thread Summary
The discussion revolves around calculating the angular momentum of a rotating disk with a mass of 3.1 kg and a diameter of 4.5 cm. The correct formula for angular momentum is L = Iw, where I is the moment of inertia and w is the angular velocity. The user initially miscalculated by using the diameter instead of the radius and confused linear velocity with angular velocity. After correcting the calculations, they found the angular momentum to be 0.049 kg*m^2/s. The direction of the angular momentum can be determined using the right-hand rule.
Dark Visitor
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I need some help with this problem. Any help would be greatly appreciated. It is due tonight.

http://session.masteringphysics.com/problemAsset/1035644/7/knight_Figure_13_47.jpg

Use the link above to solve the problem.

Part 1) What is the magnitude of the angular momentum of the 3.1 kg, 4.5-cm-diameter rotating disk in the figure ?

Part 2) What is it's direction?

For the first part, I think I need to use the equation L=Iw, but I got it wrong when I did, so I may have used the wrong numbers. If I am using the wrong equation, please tell me.
 
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As I stated in your other thread, show your work. We can't help you if we can't see where you are going wrong in your solution.
 
Well, as I said in this thread, I attempted it using the equation I posted and got it wrong. That's why I thought I needed to do for this problem, but I was wrong. Now I need help on finding where I went wrong and what to do next.
 
Yeah, but you didn't post what formula you used for the moment of inertia, or any of the steps of your calculation, so I have no idea whether you got the wrong answer because you made a calcuation error, or whether it was because you used the wrong moment of inertia equation.

Angular momentum is always given by L = Iw, so your "big picture" conceptual approach to solving the problem is correct. You are aware of all of the physics you need to know. It's just the details that need sorting out. If I can't see any of those details, I can't help you.
 
Nevermind. I realized I used the diameter in the Inertia equation instead of the radius. I will show you what I did anyways.

First I calculated that 600 RPM is equal to 62.83185 m/s. I then plugged that into the equation L=Iw, which gave me:

L = .5(M)(R)^2
= (.5(3.1 kg)(.0225 m)^2) * 62.83185 m/s
= .049 kg*m^2/s

And that was right. Now how would I get the direction of all that for Part 2?
 
Dark Visitor said:
First I calculated that 600 RPM is equal to 62.83185 m/s. I then plugged that into the equation L=Iw, which gave me:

You mean 62.83 1/s, right? (or radians per second, if you prefer to call it that). Velocity and angular velocity don't have the same units, because they aren't the same thing

Dark Visitor said:
And that was right. Now how would I get the direction of all that for Part 2?

The answer hasn't changed since the last time you were asked this question. The relationship between the direction of the angular momentum vector and the rotation direction is still given by the right hand rule.
 
Thanks. I figured it out shortly after you got off I think.
 

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