Question

Question: A uniform solid sphere rolls down an incline. (a) What must be the incline angle if the linear acceleration of the centre of the sphere is to have a magnitude of 0.10 g? (b) If a frictionless block were to slide down the incline at that angle, would its acceleration magnitude be more than, less than, or equal to0.10 g? Why?

Short answer

Answer

1. $\theta ={80}^0$
   
2. Acceleration of frictionless block will be greateras compared to 0.1 xg

Step-by-step solution

Given

The magnitude of acceleration of the center of the sphere,${\text{a}}_{\text{center}}=0.10\times \text{g}$

To understand the concept

The change in velocity per unity time interval is known as acceleration. For small angular displacements, it can also be defined as the product of angular acceleration and the radius of the path on which it is traveling. It is given as-

$\mathbf{a}\mathbf{=}\mathbf{r}\mathbf{\times }\mathbf{\alpha }$

Here, ais the acceleration,$\mathbf{\alpha }$ is the angular acceleration, and r is the radius of the circular path.

Calculate the incline angle if the linear acceleration of the centre of the sphere is to have a magnitude of 0.10 g

Let a frictional force acts on the sphere at the point of contact of sphere and the inclined plane. As the weight and normal reaction act on the center of mass, the torque produced by them is zero. So, the rotations are only caused by the frictional force. So, referring to the figure, the translational equation of motion is -

$f_s-Mg\sin \theta =Ma····························\left(1\right)$

The rotational equation of motion is given as-

$$\begin{gathered} R{f}_s=I_{com}\alpha \\ {f}_s=\frac{I_{com}\alpha }{R}······························\left(2\right) \end{gathered}$$

As we know,$\alpha =-\frac{\text{a}}{\text{R}}$ , equation (2) becomes-

$f_s=-\frac{I_{com}a}{R^2}$

Negative sign arises due to the fact that the acceleration is along the negative x axis.

From equation (1), we have,

$$\begin{gathered} -\frac{I_{com}a}{R^2}-Mg\sin \theta =Ma \\ -Mg\sin \theta =Ma+\frac{I_{com}a}{R^2} \\ -Mg\sin \theta =a\left(\frac{M{R}^2+I_{com}}{R^2}\right) \\ a=-\frac{Mg\sin \theta }{\left(\frac{M{R}^2+I_{com}}{R^2}\right)} \end{gathered}$$

Further solving,

$$\begin{gathered} a=-\frac{Mg\sin \theta }{\left(\frac{M{R}^2+I_{com}}{R^2}\right)} \\ =-\frac{g\sin \theta }{\left(\frac{R^2+I_{com}}{R^2}\right)} \end{gathered}$$

Now, putting the value of$I_{com}=\frac{2}{5}M{R}^2$for sphere

$a=-\frac{g\sin \theta }{1+\left(\frac{\frac{2}{5}M{R}^2}{M{R}^2}\right)}$

From the given data, we have a= - 0.10g so we can solve it as

$$\begin{gathered} -0.10\times g=-\frac{g\sin \theta }{1+\left(\frac{\frac{2}{5}M{R}^2}{M{R}^2}\right)} \\ -0.10\times g=-\frac{g\sin \theta }{7/5} \\ \sin \theta =\frac{7\times 0.1}{5} \\ \theta ={\sin }^{-1}\left(0.14\right) \end{gathered}$$

Further solving,

$\theta =8.0^0$

Find out if the acceleration magnitude would be more than, less than, or equal to if a frictionless block were to slide down the incline at the angle

The acceleration would be greater than that of 0.1xg

If the block is frictionless, there would be no frictional force opposing the motion. The component of the gravitational acceleration will cause net acceleration of the object. It is not resisted by the frictional force, so overall acceleration would be the same as that of the component of the gravitational acceleration. This would be greater than 0.1g