If velocity of an electron is `(2 hati + 3hatj) ms^(-1)` and it enters in the magnetic field of `4 hatkT` , then

A projectile is thrown with an initial velocity of (a hati +b hatj) ms^(-1) . If the range of the projectile is twice the maximum height reached by it, then

If the velocity of a particle is (2hati+3hatj-4hatk) and its acceleration is (-hati+2hatj+hatk) and angle between them in (npi)/(4) . The value of n is .

A particle has velocity (6t^3hati+8t^2hatj) ms^(-1) find the velocity of the particle

A cricket ball of mass 150 g has an initial velocity mu=(3hati+4hatj) ms^(-1) and a final velocity v = - (3hat(i) + 4hat(j)) ms^(-1) , after being hit. The change in momentum (final momentum­initial momentum) is (in kgms^(-1) )

A vector perpendicular to (4hati-3hatj) may be :

Dipole moment of coil is 2hati+3hatj+5hatk . If this coil is placed in uniform magnetic field having magnitude 3hatkT , torque acting on it is _____ Nm.

The velocity of a projectile at the initial point A is (2hati+3hatj) m//s . Its velocity (in m/s) at point B is

An electron is moving with an initial velocity vecv=v_(0)hati and is in a magnetic field vecB=B_(0)hatj Then it's de-Broglie wavelength

The velocity of projection of oblique projectile is (6hati+8hatj)ms^(-1) The horizontal range of the projectile is

In a reference frame a man A is moving with velocity (3hati-4hatj)ms^(-1) and another man B is moving with velocity (hati+hatj)ms^(-1) relative to A. Find the actual velocity of B.