Example 5.1 Worked on the Board!
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Transcript of Example 5.1 Worked on the Board!
Example 5.1 Worked on the Board!
• Find the gravitational potential Φ inside & outside a spherical shell, inner radius b, outer radius a. (Like a similar electrostatic potential problem!)
• This is an important & fundamental problem in gravitational theory! If you understand this, you understand the gravitational potential concept! (& probably the electrostatic potential concept as well!) .
• Could approach the spherical shell using forces directly (Prob. 5.6), but its MUCH easier with the potential!
• Find Φ inside & outside a spherical shell of mass M, mass density ρ, inner radius b & outer radius a.
Φ = -G∫[ρ(r)dv/r]. Integrate over V. The difficulty, of course, is properly setting up the integral! If properly set up, doing it is easy!
Recall Spherical Coordinates
Outline of Calculation!
Summary of Results M (4π)ρ(a3 - b3) outside the shell
R > a, Φ = -(GM)/R (1) The same as if M were a point mass at the origin!
completely inside the shell R < b, Φ = -2πρG(a2 - b2) (2)Φ = constant, independent of position.
within the shell b R a, Φ = -4πρG[a2- (b3/R) - R2] (3)
• Also, Φ is continuous! If R a, (1) & (3) are the same! If R b, (2) & (3) are the same!
• These results are very important, especially
those for R > a, Φ = -(GM)/R This says: The potential at any point outside
a spherically symmetric distribution of matter (shell or solid; a solid is composed of infinitesimally thick shells!) is independent of the size of the distribution & is the same as that for a point mass at the origin.
To calculate the potential for such a distribution we can consider all mass to be concentrated at the center.
• Also, the results are very important for
R < b, Φ = -2πρG(a2 - b2)
The potential is constant anywhereinside a spherical shell. The force on a test mass m inside the shell is 0!
• Given the results for the potential Φ, we can compute the GRAVITATIONAL FIELD g inside, outside & within the spherical shell: g - Φ
• Φ depends on R only g is radially directed g = g er = - (dΦ/dR)er [M (4π)ρ(a3 - b3)] outside the shell R > a, g = - (GM)/R2 The same as if M were a point mass at the origin!
completely inside the shell R < b, g = 0 Since Φ = constant, independent of position.
within the shell b R a, g = (4π)ρG[(b3/R2) - R]
• Plots of the potential Φ & the field g inside, outside & within aspherical shell. g - Φg = - (dΦ/dR)
g = - (GM)/R2
g = 0
Φ = -(GM)/R
Φ = constant