An electric field `vec(E)=B x hat(i)` exists in space, where `B = 20 V//m^(2)`. Taking the potential at (2m, 4m) to be zero, find the potential at the origin.

An electric field vec(E ) = hat(i) Cx exists in the space, where C = 10 V/ m^(2) . Taking the potential at (10 m, 20 m ) to be zero, find the potential at the origin.

An electric field vecE = vec I Ax exists in the space, where A= 10 V m ^(-2). Take the potential at (10m, 20m ) to be zero. Find the potential at the origin.

An electric field vecE = vec I Ax exists in the space, where A= 10 V m ^(-2). Take the potential at (10m, 20m ) to be zero. Find the potential at the origin.

An electric field vecE = vec I Ax exists in the space, where A= 10 V m ^(-2). Take the potential at (10m, 20m ) to be zero. Find the potential at the origin.

Assume that an electric field vec(E) = 30 x^(2) hat(i) exists in space. Then the potential differences V_(A) - V_(0) where V_(0) is the potential at the origin and V_(A) , the potential at x = 2m is

An electric field vec(E)=(10 hat(i) + 20 hat(j)) N//C exists in the space. If the potential at the origin is taken to be zero, find the potential at (3m, 3m).

Assume than an electric field vec(E ) = 30 x^(2)hat(i) exists in space. Then the potential difference V_(A) - V_(O) , where V_(O) is the potential at the origin and V_(A) the potential at x = 2 m is

Assume that an electric field vec(E) = 30 x^(2) hat(i) exists in space. Then the potentail differences V_(A) - V_(0) where V_(0) is the potential at the origin and V_(A) , the potebntail at x = 2m is

An electric field vecE = (20i + 30j) NC^(-1) exists in the space. If the potential at the origin is taken to be zero find the potential at (2m, 2m).