If `vec(j)` and `vec(E )` are current density and electric field inside a current carrying conductor at an instant then `vec(j). vec( E )` is
(1) Positive (2) Negative
(3) Zero (4) May be positive or negative

If vec(j) and vec(E ) are current and electric field inside a current carrying conductor at an instant then vec(j). Vec( E ) is (1) Positive (2) Negative (3) Zero (4) May be positive or negative

If vec(j) and vec(E ) are current density and electric field respectively inside a current carrying conductor , then correct relation is

Let vec(M) and vec(L) represent magnetic moment and angular momentum vectors for the electron in the above example. What is the sign of the dot product, vec(M).vec(L) . (positive, negative or zero) ?

The electric field intensity vec(E) , , due to an electric dipole of dipole moment vec(p) , at a point on the equatorial line is :

Assetrion: Net electric field insider conductor is zero Reason: Total positive charge equals to total negative charge in a conductor

If vec(E)_(1) and vec(E)_(2) are electric field at axial point and equatorial point of an electric dipole, then (1) vec(E)_(1).vec(E)_(2)gt 0 (2) vec(E)_(1).vec(E)_(2)=0 (3) vec(E)_(1).vec(E)_(2)lt 0 (4) vec(E)_(1)+vec(E)_(2)=vec(0)

Electric field on the axis of a small electric dipole at a distance r is vec(E)_(1) and vec(E)_(2) at a distance of 2r on a line of perpendicular bisector is

What is current density? Write the vector equation connecting current density J with electric field intensity E for an ohmic conductor.

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