Due to a charge inside a cube the electric field is `E_(x)=600 x^(1//2), E_(y)=0, E_(z)=0`. The charge inside the cube is (approximately):

If the electric field components due to electric charge in cube shown in figure are E_x = 600x^(1/2) and E_y = 0 and E_z = 0 , then charge within the cube…………

The electric field components are E_(x)=ax^(-1//2),E_(y)=E_(z)=0 in which a =800 N/C m^(1//2) calculate (a) the flux through the cube and (b) the charge within the cube asume that a=0.1 m

Component of electric field of electromagnetic wave is as following : E_(x)=10^(2)sin(pi(9xx10^(14)t-3xx10^(6)z)) , E_(y)=0, E_(z)=0 , then intensity of wave is ….

(a) Show that the normal component of electrostatic field has a discontinuity from one side of a charged surface to another given by (E_(2)-E_(1)).n = sigma/epsilon_(0) where hatn is a unit vector normal to the surface at a point and sigma is the surface charge density at that point. (The direction of hatn is from side 1 to side 2.) Hence, show that just outside a conductor, the electric field is sigma hatn //epsilon_(0) . (b) Show that the tangential component of electrostatic field is continuous from one side of a charged surface to another. [Hint: For (a), use Gauss’s law. For, (b) use the fact that work done by electrostatic field on a closed loop is zero.]

If the total charge enclosed by a surface is zero, does it imply that the electric field everywhere on the surface is zero ? Conversely, if the electric field everywhere on a surface is zero, does it imply that net charge inside is zero.

A particle of mass m and charge q has an initial velocity vecv =v_(0)hatj . If an electric field E = E_(0)hati and B = B_(0)hati magnetic field act on the particle, its speed will double after a time

Inside a parallel plate capacitor the electric field E varies with time as t^2 . The variation of induced magnetic field with time is given by ......

When two concentric shells are connected by a thin conducting wire, whole of the charge of inner shell transfers to the outer shell and potential difference between them becomes zero. Surface charge densities of two thin concentric spherical shells are sigma and -sigma respectively. Their radii are R and 2R . Now they are connected by a thin wire. Suppose electric field at a distance r (gt 2R) was E_(1) before connecting the two shells and E_(2) after connecting the two shells, then |E_(2)/E_(1)| is :-

When two concentric shells are connected by a thin conducting wire, whole of the charge of inner shell transfers to the outer shell and potential difference between them becomes zero. Surface charge densities of two thin concentric spherical shells are sigma and -sigma respectively. Their radii are R and 2R . Now they are connected by a thin wire. Suppose electric field at a distance r=(3R)/2 was E_(1) before connecting the two shells and E_(2) after connecting the two shells, then |E_(2)/E_(1)| is :-