Ncert Exercises & Solutions

Question 7. 33. Separation of Motion of a system of particles into the motion of the center of mass and motion about the center of mass:

Show pi = p’i + miV

Where pi is the momentum of the i
th particle (of mass mi) and p′ i = mi v′ i. Note v′ i is the
velocity of the i
th particle relative to the centre of mass.

Also, prove using the definition of the centre of mass $\sum p_{i}^{'} = 0$

Show K = K′ + ½MV2

Where K is the total kinetic energy of the system of particles, K′ is the total kinetic energy of the system when the particle velocities are taken with respect to the center of mass and MV2/2 is the kinetic energy of the translation of the system as a whole (i.e. of the center of mass motion of the system). The result has been used in Sec. 7.14.

Show L = L′ + R × MV

Where $L^{'} = \sum_{i} r^{'} \times p_{i}^{'}$ is the angular momentum of the system about the center of mass with velocities taken relative to the center of mass? Remember r’i = ri – R; rest of the notation is the standard notation used in the chapter. Note L′ and MR × V can be said to be angular momenta, respectively, about and of the center of mass of the system of particles.

Show $\frac{{dL}^{'}}{dt} = \sum_{i} r_{i}^{'} \times \frac{d}{dt} (p_{i}^{'})$

$\frac{d L^{'}}{d t} = τ_{e x t}^{'}$

Further, show that

where τ′ext is the sum of all external torques acting on the system about the center of mass.

(Hint: Use the definition of center of mass and Newton’s Third Law. Assume the internal forces between any two particles act along the line joining the particles.)

(a)Take a system of i moving particles.
Mass of the i
th particle = mi
Velocity of the i
th particle = vi
Hence, momentum of the i
th particle, pi = mi vi
Velocity of the centre of mass = V
The velocity of the i
th particle with respect to the centre of mass of the system is given
as: v’i = vi – V … (1)
Multiplying mi throughout equation (1), we get:
mi v’i = mi vi – mi V
p’i = pi – mi V
Where,

pi’ = mivi’ = Momentum of the i
th particle with respect to the centre of mass of the
system pi = p’i +mi V
We have the relation: p’i = mivi’
Taking the summation of momentum of all the particles with respect to the centre of mass of the system, we get:

$\sum p_{i}^{'} = \sum m_{i} v_{i}^{'} = \sum m_{j} \frac{d r_{i}^{'}}{d t}$

$\begin{array}{l} Where, \\ r^{'} = Position vector of ith particle with respect to the centre of mass \\ v_{i}^{'} = \frac{{dr}_{i}^{'}}{dt} \end{array}$

As per the definition of the center of mass, we have:

$\begin{array}{l} \sum m_{i} r_{i}^{'} = 0 \\ ∴ \sum_{i} m_{j} \frac{{dr}_{j}^{'}}{dt} = 0 \\ \sum p_{i}^{'} = 0 \end{array}$

We have the relation for velocity of the ith particle as:

$v_{i} = v_{i}^{'} + V$

$\sum_{i} m_{i} v_{i} = \sum_{i} m_{i} v_{i}^{'} + \sum_{i} m_{i} V$ ...(2)

Taking the dot product of equation (2) with itself, we get:

$\begin{array}{l} \sum_{j} m_{i} v_{i} \sum_{i} m_{i} v_{i} = \sum_{i} m_{i} (v_{i}^{'} + V) \cdot \sum_{i} m_{i} (v_{i}^{'} + V) \\ M^{2} \sum v_{i}^{2} = M^{2} \sum v_{i}^{' 2} + M^{2} \sum v_{i} v^{'} + M^{2} \sum v^{'} v_{i} + M^{2} V^{2} \end{array}$

Here, for the centre of mass ofthe system of particles. $\sum v_{i} v_{i}^{'} = - \sum_{i} v_{i}^{'} v$

$\begin{array}{l} M^{2} \sum_{i} v_{i}^{2} = M^{2} \sum_{i} v_{i}^{' 2} + M^{2} V^{2} \\ \frac{1}{2} M \sum_{i} v_{i}^{2} = \frac{1}{2} M \sum v_{1}^{' 2} + \frac{1}{2} {MV}^{2} \\ K = K^{'} + \frac{1}{2} {MV}^{2} \end{array}$

Where,
$K = \frac{1}{2} M \sum v_{i}^{2}$ = Total kinetic energy of the system of particles
$K = \frac{1}{2} M \sum v_{i}^{' 2}$ = Total kinetic energy of the system of particles with respect to the
centre of mass
$\frac{1}{2} M V^{2}$ = Kinetic energy of the translation of the system as a whole Position vector of the ith particle with respect to origin = ri

Position vector of the i
th particle with respect to the centre of mass = r’i
Position vector of the centre of mass with respect to the origin = R
It is given that: r’i = ri
– R ri = r’i + R We
have from part (a), pi
= p’i +mi V
Taking the cross product of this relation by ri, we get:

$\begin{array}{l} \sum_{i} r_{i} \times p_{i} = \sum_{i} r_{i} \times p_{i}^{'} + \sum_{i} r_{i} \times m_{i} V \\ L = \sum_{i} (r_{i}^{'} + R) \times p_{i}^{'} + \sum_{i} (r_{i}^{'} + R) \times m_{i} V \\ = \sum_{i} r_{i}^{'} \times p_{i}^{'} + \sum_{i} R \times p_{i}^{'} + \sum_{i} r_{i}^{'} \times m_{i} V + \sum_{i} R \times m_{i} V \\ = L^{'} + \sum R \times p_{i}^{'} + \sum r_{i}^{'} \times m_{i} V + \sum R \times m_{i} V \end{array}$

Where,

$\begin{array}{l} R \times \sum_{i} p_{i}^{'} = 0 and \\ (\sum_{i} r_{i}^{'}) \times MV = 0 \\ \sum_{i} m_{i} = M \\ ∴ L = L^{'} + R \times MV \end{array}$

We have the relation:

$\begin{array}{l} L^{'} = \sum_{i} r_{i}^{'} \times p_{i}^{'} \\ \frac{{dL}^{'}}{dt} = \frac{d}{dt} (\sum r_{i}^{'} \times p_{1}^{'}) \end{array}$
$\begin{array}{l} = \frac{d}{dt} (\sum r_{i}^{'}) \times p_{i}^{'} + \sum_{i} r^{'}, \times \frac{d}{dt} (p_{i}^{'}) \\ = \frac{d}{dt} (\sum_{i} m_{i} r_{i}^{'}) \times v_{i}^{'} + \sum_{j} r_{i}^{'} \times \frac{d}{dt} (p_{i}^{'}) \end{array}$

Where. r', is the position vector with respect to the center of mass of the system of particles.

$\begin{array}{l} ∴ \sum m_{i} r_{i}^{'} = 0 \\ ∴ \frac{{dL}^{'}}{dt} = \sum r_{i}^{'} \times \frac{d}{dt} (p_{i}^{'}) \end{array}$

We have the relation:

$\begin{array}{l} \frac{{dL}^{'}}{dt} = \sum_{i} r_{i}^{'} \times \frac{d}{dt} (p_{i}^{'}) \\ = \sum_{i} r_{i}^{'} \times m_{i} \frac{d}{dt} (v_{i}^{'}) \end{array}$

Where, $\frac{d}{dt} (v_{i}^{'})$ is the rate of change of velocity of the ith particle with respect to the center of mass of the system

Therefore, according to Newton's third law of motion, we can write:

$\begin{array}{l} m_{i} \frac{d}{d t} (v_{i}^{'}) = Extrenal force acting on the i th particle = \sum_{i} (τ_{i}^{'}) \\ i.e., \sum_{i} r_{i}^{'} \times m_{i} \frac{d}{d t} (v_{i}^{'}) = τ_{et}^{'} = External torque acting on the system as a whole \end{array}$
$∴ \frac{d L^{'}}{d t} = τ_{e x f}^{'}$

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