Question

A solid uniform-density sphere is tied to a rope and moves in a circle with speed $\mathbf{v}$. The distance from the center of the circle to the center of the sphere is $\mathbf{d}$, the mass of the sphere is $\mathbf{M}$, and the radius of the sphere is$\mathbf{R}$. (a) What is the angular speed role="math" localid="1653899021129" $\mathit{\omega }$? (b) What is the rotational kinetic energy of the sphere? (c) What is the total kinetic energy of the sphere?

Short answer

(a) $\frac{v}{d}$

(b) $\frac{1}{2}\left(\frac{2}{5}M{R}^2\right){\left(\frac{v}{d}\right)}^2$

(c) $\frac{1}{2}\left(M{d}^2+\frac{2}{5}M{R}^2\right){\left(\frac{v}{d}\right)}^2$

Step-by-step solution

Identification of the given data

The given data is listed below as,

• The velocity of the solid-uniform density sphere is $v$.
• The distance from the center of the circle to the center of the sphere is $d$.
• The sphere’s mass is $M$.
• The sphere’s radius is $R$.

Significance of the moment of inertia of the sphere

The moment of inertia for a body state that the force that a body exhibits while rotating about an axis is due to the application of a turning force which is torque.

The equation of the rotational kinetic energy of the sphere can be expressed as,

${\text{K.E}}_R=\frac{1}{2}{\rm I}{\omega }^2$ …(1)

Here,$I$ is the moment of inertia of the sphere and $\omega$is the angular velocity of the sphere.

The equation of the translational kinetic energy of the sphere is be expressed as,

$K.E_T=\frac{1}{2}M{v}^2$ …(2)

Here, $M$ is the mass of the sphere and$v$ is the velocity of the sphere at center of mass of the sphere.

Determination of the angular speed

(a)

The equation of the angular speed can be expressed as,

$\omega =\frac{v}{r}$

Here, $v$is the velocity and $r$ is the distance of the centre of the circle to the centre of the sphere.

For$r=d$,

$\omega =\frac{v}{d}$

Thus, the angular speed is $\omega =\frac{v}{d}$.

Determination of the rotational energy

(b)

The expression for the moment of inertia of the sphere is expressed as,

$I=\frac{2}{5}M{R}^2$

Here, $M$is the mass of the sphere and $R$is the radius of the sphere.

For $I=\frac{2}{5}M{R}^2$and $\omega =\frac{v}{d}$in equation (1).

$$\begin{gathered} K.E_R=1/2\times 2/5M{R}^2\times {\left(v/d\right)}^2 \\ =1/2\left(2/5M{R}^2\right){\left(v/d\right)}^2 \end{gathered}$$

Thus, the rotational kinetic energy of the sphere is $\frac{1}{2}\left(\frac{2}{5}M{R}^2\right){\left(\frac{v}{d}\right)}^2$.

Determination of the total kinetic energy

(c)

For $v=\omega d$in equation (2).

$$\begin{gathered} K.E_T=1/2M{\left(\omega d\right)}^2 \\ =1/2M{d}^2 \end{gathered}$$

The expression for the total kinetic energy is expressed as,

$K.E=K.E_T+K.E_R$

For $K.E_T=\frac{1}{2}M{d}^2$and ${\text{K.E}}_R=\frac{1}{2}\left(\frac{2}{5}M{R}^2\right){\left(\frac{v}{d}\right)}^2$.

$$\begin{gathered} K.E=1/2M{d}^2+1/2\left(2/5M{R}^2\right){\left(v/d\right)}^2 \\ =1/2\left(M{d}^2+2/5M{R}^2\right){\left(v/d\right)}^2 \end{gathered}$$

Thus, the total kinetic energy of the sphere is $\frac{1}{2}\left(M{d}^2+\frac{2}{5}M{R}^2\right)\times {\left(\frac{v}{d}\right)}^2$.