Electric field in xy plane is directed along positive y direction and its magnitude changes with y co-ordinate as `E=ay^(2)`
A particle having charge q and mass m is projected at point (0,`y_(0)`) with velocity
`vecv=v_(0)hati`
Neglect all other forces o the particle apart from the electric force. Calculate the slope of the trajectory of the particle as a function of y.

Suppose in an insulating medium, having di-electric constant k= 1, volume density of positive charge varies with y-coordinate according to law rho = ay . A particle of mass m having positive charge q is placed in the medium at point A (0,y_(0)) J and projected with velocity vecv = v_(0)hati as shown in figure. Neglecting gravity and frictional resistance of the medium and assuming electric field strength to be zero at y = 0, calculate slope of trajectory of the particle as a function of y :

A particle having mass m and charge q is projected with a velocity v making an angle q with the direction of a uniform magnetic field B. Calculate the magnitude of change in velocity of the particle after time t=(pim)/(2qB) .

A particle of charge per unit mass alpha is released from origin with a velocity vecv=v_(0)hati uniform magnetic field vecB=-B_(0)hatk . If the particle passes through (0,y,0) , then y is equal to

A uniform electric field E_0 is directed along positive y-driection. Find the change in electric potential energy of a positive test charge q_0 when it is displaced in this field from y_i=a to y_f=2a along the y-axis.

A charged particle (charge q mass m) is projected with velocity v between plates of a parallel plate capacitor as shown at t = 0. The time at which instantaneous power delivered by the electric force is zero to the particle is Ľ

A positive charge particle having change q and mass m has velocity vecv = v((hati+hatk)/sqrt2) in the magnetic field B at the origin . Its speed as the function of y is :

A charge particle of mass m and charge q is projected with velocity v along y-axis at t=0. Find the velocity vector and position vector of the particle vec v (t) and vec r (t) in relation with time.

A positively charged particle having charge q_1 = 1 C and mass m_1 =40 gm is revolving along a circle of radius R=40 cm with velocity v_1 = 5 ms^-1 in a uniform magnetic field with center of circle at origin O of a three-dimensional system. At t=0 , the particle was at (0, 0.4m, 0) and velocity was directed along positive x direction. Another particle having charge q_2 = 1 C and mass m_2 = 10g moving uniformly parallel to positive z-direction with velocity v_2 = 40//pi ms^-1 collides with revolving particle at t=0 and gets stuck to it. Neglecting gravitational force and coulomb force, calculate x-, y- and z-coordinates of the combined particle at t= pi//40 s .

A charged particle of mass m and charge q is released from rest the position (x_0,0) in a uniform electric field E_0hatj . The angular momentum of the particle about origin.

A charged particle having charge 2q and mass m is projected from origin in X-Y plane with a velocity v inclined at an angle of 45^@ with positive X-axis in a region where a uniform magnetic field B unit exists along +z axis. The coordinates of the centre of the circular path of the particle are