How Do You Correctly Cancel Angular Momentum in Physics Problems?

In summary, canceling angular momentum in physics problems involves identifying the system's total angular momentum and applying conservation laws. When external torques are absent, the angular momentum remains constant. To correctly cancel angular momentum, one must account for all contributing factors, such as mass distribution and angular velocities, ensuring that the sum of angular momenta before and after an event remains equal. It is crucial to consider both direction and magnitude, and to apply vector addition when necessary.
  • #1
pbnj
5
0
Homework Statement
A ball with mass ##m## and diameter ##D## is thrown with speed ##v## at an angle ##\theta## with the horizontal from a height ##h_i##. How much spin (in rad/s) must the thrower impart on the ball so that at its maximum height, it has no angular momentum with respect to a point on the ground directly beneath the ball?
Relevant Equations
##v_f^2 = v_i^2 + 2a\Delta h##
##L = I\omega##
##L = \vec r \times \vec p##
First, we calculate the maximum height using the first equation, noting that at maximum height, the velocity is purely horizontal with speed ##v\cos\theta##, and with initial vertical speed ##v\sin\theta##:

$$
\begin{align}
v_f^2 &= v_i^2 - 2g(h_f - h_i) \\
0 &= (v\sin\theta)^2 - 2g(h_f - h_i) \\
h_f &= \frac{(v\sin\theta)^2}{2g} + h_i
\end{align}
$$

The angular momentum from translation is given by ##L_t = \vec r \times \vec p = h_f\hat j \times mv\cos\theta\hat i = -h_fmv\cos\theta\hat k##. The moment of inertia of a sphere is ##I = \frac 2 5 mR^2## where ##R = \frac D 2##, and its angular momentum due to spin is ##L_s = I\omega##.

We need these to cancel, so

$$
\begin{align}
L_t + L_s &= 0 \\
-h_fmv\cos\theta + \frac 2 5 mR^2\omega &= 0 \\
\omega &= \frac{h_fmv\cos\theta}{\frac 2 5 mR^2} \\
&= \frac{5h_fv\cos\theta}{2R^2}
\end{align}
$$

The problem uses ##m = 625g##, ##D = 22.9cm##, ##\theta = 45^\circ##, ##v=5m/s## and ##h_i = 1.5m##. Using these values I get a spin of about ##1440.82##, in rad/s.
 
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  • #2
Your answer agrees with mine.
 
  • #3
pbnj said:
Using these values I get a spin of about 1440.82, in rad/s.
Have you a reason to doubt it?
 
  • #4
haruspex said:
Have you a reason to doubt it?
It's for a Coursera course, and it tells me it's incorrect. I've tried incrementing/decrementing my answer by 5 a few times, I tried using 2 sigfigs for everything, I tried assuming "diameter" meant "radius," but no luck. On the discussion forum there are no questions about this particular answer (the course is 3 years old, and it doesn't seem like new posts get replies). If my approach is correct and my calculations are correct, I can only assume something in the backend changed in the 3 years between then and now.
 

FAQ: How Do You Correctly Cancel Angular Momentum in Physics Problems?

What is angular momentum and why is it important in physics problems?

Angular momentum is a measure of the rotational motion of an object and is a vector quantity, which means it has both magnitude and direction. It is important in physics because it is conserved in isolated systems, making it a fundamental concept for analyzing rotational dynamics and solving problems related to rotational motion.

How do you determine the direction of angular momentum?

The direction of angular momentum is determined using the right-hand rule. Point your fingers in the direction of the object's rotation (curl them if necessary), and your thumb will point in the direction of the angular momentum vector. This rule helps in visualizing and solving problems involving rotational motion.

What are the common methods to cancel angular momentum in physics problems?

Common methods to cancel angular momentum include applying equal and opposite torques, using counter-rotating masses, and utilizing conservation laws. By ensuring that the net angular momentum of a system is zero, you can effectively cancel out any rotational motion.

How does the conservation of angular momentum help in solving physics problems?

The conservation of angular momentum states that if no external torque acts on a system, its total angular momentum remains constant. This principle helps in solving physics problems by allowing you to set up equations where the initial and final angular momentum are equal, simplifying the analysis of rotational systems.

Can you provide an example problem where angular momentum is canceled and explain the solution?

Consider a figure skater spinning with arms extended. When the skater pulls their arms in, they reduce their moment of inertia, causing them to spin faster to conserve angular momentum. To cancel this increased angular momentum, the skater can extend their arms again, increasing their moment of inertia and slowing their rotation. This demonstrates how adjusting the distribution of mass can cancel or control angular momentum in a system.

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