An electric field given by `vec(E )= 4hat(i)+3(y^(2)+2)hat(j)` pieces Gaussian cube side `1m` placed at origin such that is three sides represents `x,y` and `z` axis. This net charge enclosed within the cube is

An electric field given by vec(E) = 4hat(i) - (20 y^(2) + 2) hat(j) pierces a Gussian cube of side 1 m placed at origin such that its three sides represents x,y and z axes. The net charge enclosed within the cube is x xx 10^(-10)C , where is _____. (take in_(0) = 8.85 xx 10^(-12) N^(-1)m^(-2)C^(2) )

An electric field given by vec(E) = 4hat(i) - (20 y^(2) + 2) hat(j) pierces a Gussian cube of side 1 m placed at origin such that its three sides represents x,y and z axes. The net charge enclosed within the cube is x xx 10^(-10)C , where is _____. (take in_(0) = 8.85 xx 10^(-12) N^(-1)m^(-2)C^(2) )

An electric field given by vec(E)=4hat(i)+3(y^(2)+2) hat(j) pierces a gaussian cube of side 1m placed at origin such that one of its corners is at origin and rest of sides are along positive side of coordinate axis. Find the magnitude of net charge enclosed within the cube [3 in_(0)]

The potential field of an electric field vec(E)=(y hat(i)+x hat(j)) is

The potential field of an electric field vec(E)=(y hat(i)+x hat(j)) is

The potential field of an electric field vec(E)=(y hat(i)+x hat(j)) is

If vec(E)=2x^(2) hat(i)-3y^(2) hat(j) , then V (x, y, z)

If vec(E)=2x^(2) hat(i)-3y^(2) hat(j) , then V (x, y, z)