A square of side 'a' is lying in xy plane such that two of its sides are lying on the axis. If an electric field `vec(E)=E_(0)xhat(k)` is applied on the square. The flux passing through the square is :

A square of side x m lies in the x-y plane in a region, when the magntic field is given by vecB=B_(0)(3hati+4hatj+5hatk) T, where B_(0) is constant. The magnitude of flux passing through the square is

A cube of side a is placed in a uniform electric field E = E_(0) hat(i) + E_(0) hat(j) + E_(0) k . Total electric flux passing through the cube would be

A point charge Q is placed at the corner of a square of side a. Find the flux through the square.

A square plate of side 'a' and mass 'm' is lying on a horizontal floor. A force F is applied at the top. Find the maximum force that can be applied on the square plate so that the plate does not topple about A.

A square surface of side L m is in the plane of the paper. A uniform electric field vec(E )(V//m) , also in the plane of the paper, is limited only to the lower half of the square surface (see figure). The electric flux in SI units associated with the surface is:

A square of side L meters lies in the x-y plane in a region, where the magnetic field is give by B = B_(0) (2 hati + 3 hat j + 4 hatk) T, where B_(0) is constant. The magnitude of flux passing through the square is

A square surface of side L metre in the plane of the paper is placed in a uniform electric field E ("volt"//m) acting along the same place at an anlge theta with the horizontal side of the square as shown in figure. The electric flux linked to the surface in uint of V-m is

There exists an electric field of 1 NC^(-1) along Y direction. The flux passing through the square of 1 m placed in xy- plane inside the electric field is

The area of the square field is 196 sq.m. Its each side is: