A cricket ball of 0.5 kg is moving with a velocity of `100ms^(-1)`. The wavelength associated with its motion is :

A body of mass 10 mg is moving with a velocity of 100 ms^(-1) . The wavelength of the de Broglie wave associated with it would be

The velocily associated wiih a proton moving in a potential difference of 1000 V is 4.37 xx 10^5 ms^(-1) . If the böckey ball of mass 0.1 kg is moving with this velocity, calculate the wavelength associated with this velocity.

A particle of mass 10^31 kg is moving with a velocity equal to 10^5ms^-1 . The wavelength of the particle is equal to

A 0.66 kg ball is moving wih a speed of 100 m//s . The associated wavelength will be.

A ball of mass 0.5 kg is moving with a velocity of 2 ms^(-1) . It if subjected to a force of x Newton for 2s. Because of this force, the ball moves with a velocity of 3ms^(-1) . The value of x is :

A cricket ball of mass 150 kg is moving with a velocity of 12 m//s and is hit by a bat so that ball is turned back with a velocity of 20 m//s . The force of the blow acts for 0.01 s on the ball . Find the average force exerted by the bat on the ball.

A cricket ball of mass 150 g is moving with a speed of 12ms^(-1) and is hit by a bat so that the ball is turned back with velocity of 20ms^(-1) if duration of contact between bat and ball is 0.01 s then:

The wavelength of an electron moving with velocity of 10^(7)ms^(-1) is

A ball of mass 200 g is moving with a velocity of 10 m sec^(-1) . If the error in measurement of velocity is 0. 1% , the uncertainty in its position is :

A body of mass x kg is moving with a velocity of 100ms^(-1) . Its de-Broglie wavelength is 6.62xx10^(-35)m . Hence, x is: (h=6.62xx10^(-34)Js)