The cube shown in Fig. 2.119 has sides of length `L = 10.0 cm` . The electric field is uniform , has a magnitude `E = 4.00 xx 10^(3) NC^(-1) ` and is parallel to the `xy` plane at an angle of `37^(@)` measured from the `+ x` - axis toward the `+ y `- axis .

The surface that have zero flux are

The cube shown in Fig. 2.119 has sides of length L = 10.0 cm . The electric field is uniform , has a magnitude E = 4.00 xx 10^(3) NC^(-1) and is parallel to the xy plane at an angle of 37^(@) measured from the + x - axis toward the + y - axis . Electric flux passing through surface S_(1) is

The cube shown in Fig. 2.119 has sides of length L = 10.0 cm . The electric field is uniform , has a magnitude E = 4.00 xx 10^(3) NC^(-1) and is parallel to the xy plane at an angle of 37^(@) measured from the + x - axis toward the + y - axis . Electric flux passing through surface S_(6) is

The cube shown in Fig. 2.119 has sides of length L = 10.0 cm . The electric field is uniform , has a magnitude E = 4.00 xx 10^(3) NC^(-1) and is parallel to the xy plane at an angle of 37^(@) measured from the + x - axis toward the + y - axis . The total net electric flux through all faces of the cube is

A vertical electric field of magnitude 4.00xx 10^5 NC^(-1) . just prevents a water droplet of mass 1.000x 10^(-4)b kg from. falling., find the charge on the droplet.

Consider a uniform electric field E = 3 xx 10^(3) hat(i)N C^(-1) . What is te flux of this field through a square of 10 cm on a side whose plane is parallel to the yz plane ?

The electric field in a region is given by vecE=3/5 E_0veci+4/5E_0vecj with E_0=2.0 xx 10^3 N C^(-1) . Find the flux of this field through a recatngular surface of area 0.2m^2 parallel to the y-z plane.

A cube has sides of length L = 0.300 m . It is placed with one corner at the origin ( refer to Fig.2.119).The electric field is not uniform but is given by vec( E) = ( -5.00 NC^(-1)) x hat(i) + (3.00 NC^(-1)) z hat(k) . The surface that have zero flux are

An uniform electric field of magnitude 5 xx 10^(4) NC^(-1) has a dipole of dipole moment 4xx 10^(-9) cm aligned at 30^(@) with the direction of field. Calculate the magnitude of torque acting on the dipole:

The electric field in a region is given by E = 3/5 E_0hati +4/5E_0j with E_0 = 2.0 x 10^3 N//C . Find the flux of this field through a rectangular surface of area 0.2 m^2 parallel to the y-z plane.