A body of mass `m_(1)` collides elastically with another body of mass `m_(2)` at rest. If the velocity of `m_(1)` after collision is `(2)/(3)` times its initial velocity, the ratio of their masses is `:`

A body of mass M_(1) collides elastically with another mass M_(2) at rest. There is maximum transfer of energy when :

A body of mass M moves with velocity v and collides elasticity with another body of mass m(M gt gt m) at rest , then the velocity of the body of mass m is

A body of mass m1 collides head on perfectly elastically with a stationary body of mass m_(2) . If velocities of m_(1) before and after the collision are v and –v/3 respectively then the value of m_(1)//m_(2) is-

A body of mass m_(1) collides elastically with a stationary body of mass m_(2) and returns along the same line with one fourth of its initial speed, then m_(1)//m_(2)=

An object of mass m_(1) collides with another object of mass m_2 , which is at rest. After the collision the objects move with equal speed in opposite direction. The ratio of the masses m_(2) : m_(1) is

A body of mass m_(1) moving with uniform velocity of 40 m/s collides with another mass m_(2) at rest and then the two together begin to moe wit h uniform velocity of 30 m/s. the ratio of their masses (m_(1))/(m_(2)) is

A body of mass 4 kg collides elastically with another body of mass 2 kg at rest. If time of collision is 0.02 sec and average impulse force acted on each body is 100N, find the velocity of 4kg body before and after collision (Assuming collision takes place on a smooth horizontal surface)

A body of mass m_(1) is moving with a velocity V. it collides with another stationary body of mass m_(2) . They get embedded. At the point of collision, the velocity of the system.