Randall D. Knight — Oscillations: Problem 76

Suppose a large spherical object, such as a planet, with radius \( R \) and mass \( M \) has a narrow tunnel passing diametrically through it. A particle of mass \( m \) is inside the tunnel at a distance \( x \leq R \) from the center. It can be shown that the net gravitational force on the particle is due entirely to the sphere of mass with radius \( r \leq x \); there is no net gravitational force from the mass in the spherical shell with \( r > x \). a. Find an expression for the gravitational force on the particle, assuming the object has uniform density. Your expression will be in terms of \( x, R, m, M, \) and any necessary constants. b. You should have found that the gravitational force is a linear restoring force. Consequently, in the absence of air resistance, objects in the tunnel will oscillate with SHM. Suppose an intrepid astronaut exploring a 150-km-diameter, \( 3.5 \times 10^{18} \text{ kg} \) asteroid discovers a tunnel through the center. If she jumps into the hole, how long will it take her to fall all the way through the asteroid and emerge on the other side?