When a ball is started out with a purely sliding motion on a slick surface like a bowling alley, it will gradually begin to rotate until eventually (if the lane is long enough) it is rolling without slipping. Suppose a bowling ball which is effectively a solid sphere with a diameter of 22 cm and a mass of 6.0 kg is started down a perfectly level alley with a coefficient of kinetic friction equal to 0.10. The ball is initially sliding with no rotation and is moving at a rate of 2.8 m/s. How fast will the center of mass of the ball be moving along the alley when it is rolling without slipping?
Solution
We will solve the problem via three different methods.
Method 1: Angular Momentum
System:
The ball as a rigid body.
Interactions:
External forces of gravity, normal force and kinetic friction.
Model:
Angular Momentum and External Torque about a Single Axis.
Approach:
Diagrammatic Representation
We begin with a free body diagram. Since this problem will deal with rotation, we must also select an axis of rotation.
In this case, the most direct (but probably not the most obvious) method of solution is to consider the angular momentum about an axis fixed at some point on the alley surface. For simplicity, we select the point at which the ball is released. By taking a point on the alley surface, we have guaranteed that there is zero net torque acting on the system (the ball) about this axis. Gravity and the normal force each create a nonzero torque, but they balance each other perfectly because they share the same moment arm and they have the same magnitude. The friction force produces no torque because it has zero lever arm.
Mathematical Representation
The angular momentum about a single axis of the ball about the axis we have chosen can be broken into two parts by considering the contribution of the translation of the ball's center of mass and the rotation of the ball about its center of mass.
Since there is zero net torque acting on the ball, the angular momentum is conserved and we can write:
We know that ωi = 0, and we also know that the ball ends up rolling without slipping. Thus, we know that:
Thus, we have:
Method 2: Dynamics
System:
The ball as a rigid body.
Interactions:
External forces of gravity, normal force and kinetic friction.
Model:
Single-Axis Rotation of a Rigid Body, Point Particle Dynamics and One-Dimensional Motion with Constant Acceleration.
Approach:
We can also approach this problem by the standard technique of treating the linear dynamics of the center of mass and the rotational dynamics of the ball about its center of mass separately. The free body diagram is the same as for method 1, but now we are calculating the torques about the center of mass of the ball. Gravity and the normal force will still produce no torque, but friction will have a non-zero lever arm, and hence produce a non-zero torque.
Thus, Newton's 2nd Law takes the form:
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and its angular counterpart is:
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The trouble is that these equations do not involve the speed of the ball. One way to bring the speed in is to use kinematics. We know that:
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Using the fact that ωi = 0 and ωf R = vx,f and substituting for ax and α using the equations we wrote above, it is possible to put these equations in the form:
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Eliminating t from the equations gives:
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Method 3: Energy
System:
The ball as a rigid body.
Interactions:
External forces of gravity, normal force and kinetic friction. Gravity is conservative while the normal force and friction are non-conservative.
Model:
Mechanical Energy, External Work, and Internal Non-Conservative Work, One-Dimensional Motion with Constant Acceleration and Point Particle Dynamics.
Approach:
Often when a speed is required, energy is an efficient way to obtain the answer. In this particular problem, angular momentum is a much faster route, but it is instructive to consider the form of the energy equations.
As the ball rolls along the alley, its height is not changing and so the gravitational potential energy is fixed (and so can be set to zero). The normal force is perpendicular to the ball's linear movement and also has no moment arm about the ball's center of mass, and so does no work that would affect the ball's linear velocity or its angular velocity. Friction, however, is anti-parallel to the ball's displacement and so it does negative work on the ball's translational kinetic energy and it has a non-zero lever arm so it does work that acts to increase the ball's angular speed. The appropriate form of the mechanical energy equation is:
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Once again, we know that ωf R = vf. We do not, however, know any relationship between x and θ at this time. The ball ends up rolling without slipping, giving the relationship between the final speeds, but it has certainly been slipping in the interim. Thus, the angular distance covered will not be directly related to the linear distance. To solve this problem, we must assume that the acceleration and angular acceleration are constant. In that case, we know from kinematics that:
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We also know, as was used in Method 2, above, that:
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Substituting appropriately into the energy equation and using the rolling without slipping condition then gives the same answer as was obtained via methods 1 and 2.
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