Proof of disk moment of inertia using area density

AI Thread Summary
The discussion focuses on deriving the moment of inertia for a disk using area density. The participant initially struggles with the area element, questioning why the differential area is expressed as 2πr(dr) instead of πr^2. They clarify that the area of a circular ring is indeed 2πr(dr), leading to the correct integration for the moment of inertia. After performing the integration and substituting the appropriate values, they successfully derive the moment of inertia as MR²/2. The conversation highlights the importance of understanding the geometry of the disk in the calculation process.
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Homework Statement



Disk with radius R

σ = M/A

I = ∫ mr2

Homework Equations



Today we learned how to derive various moments of inertia via density equations (M/L, M/A, M/V). I understand all of them except on how to get MR2/2 for a disk.

The Attempt at a Solution



I = ∫mr2

σ = M/A

dM = σdA

A = πr(dr) <--- I know my problem is here and that it should be 2πr(dr). My question is why is this true? The area of a circle is πr^2 so why would an individual section have an are of 2πr(dr)?

I = σdAr2

I = ∫ σ(2πr)(r2)(dr)

I = σ(2π) ∫ r3 (dr)

∫ r3 (dr) = r4/4

Add back constants and substitute R in for r because integration is from 0 to R

I = R4/4 (σ) (2π) = R4/4 (M/A) (2π)

I = R4/4 (M/(πR2)) (2π)

I = MR2/2
 
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