A particle of mass` m_(1)` is moving with a velocity `v_(1)` and another particle of mass `m_(2)` is moving with a velocity `v_(2)`. Both of them have the same momentum, but their different kinetic energies are `E_(1) "and" E_(2)` respectively. If `m_(1)gtm_(2)`, then

A particle of mass m1 is moving with a velocity v_(1) and another particle of mass m_(2) is moving with a velocity v2. Both of them have the same momentum but their different kinetic energies are E1 and E2 respectively. If m_(1) gt m_(2) then

The de - Broglie wavelength associated with the particle of mass m moving with velocity v is

A particle of mass 2m moving with velocity v strikes a stationary particle of mass 3m and sticks to it . The speed of the system will be

A particle of mass m is projected upword with velocity v=(v_(e))/(2) ( v_(e)) escape of the particle is

A particle of mass m is moving with a uniform velocity v_(1) . It is given an impulse such that its velocity becomes v_(2) . The impulse is equal to

What is the momentum of an object of mass m , moving with a velocity v ?

A particle of mass m moves along line PC with velocity v as shown. What is the angular momentum of the particle about O ?

A particle of mass m_(1) = 4 kg moving at 6hatims^(-1) collides perfectly elastically with a particle of mass m_(2) = 2 moving at 3hati ms^(-1)

A particle of mass m_1 moving with velocity v in a positive direction collides elastically with a mass m_(2) moving in opposite direction also at velocity v. If m_(2)gt gtm_(1) , then

A body of mass m_(1) moving with an unknown velocity of v_(1)hat i , undergoes a collinear collision with a body of mass m_(2) moving with a velocity v_(2) hati . After collision , m_(1) and m_(2) move with velocities of v_(3) hati and V_(4) hati , respectively. If m_(2)=0.5 m_(1) and v_(3)=0.5v_(1) , then v_(1) is :