Recall from MECHANICS that if we move a particle
a vector distance
under the influence of
a force ,
that force does
worth of work on the particle -
which appears as kinetic energy. Etc.
If the force is due to the action of an electric field
on a charge q, the work done is
.
This work gets ``stored up'' as potential energy V
as usual: dV = -dW.
Just as we defined
as the force per unit charge,
we now define the ELECTRIC POTENTIAL
to be the
potential energy per unit charge, viz.
Just as we quickly adapted our formulation of MECHANICS
to use energy (potential and kinetic) as a starting point
instead of force, in &
we usually find it easier to
start from
as a function of position
and derive
the same way we did in MECHANICS:
(17.14) |
The most important example is, of course, the electric potential
due to a single ``point charge'' Q at the origin:
Electric potential is most commonly measured in volts (abbreviated V) after Count Volta, who made the first useful batteries. We often speak of the ``voltage'' of a battery or an appliance. [The latter does not ordinarily have any electric potential of its own, but it is designed to be powered by a certain ``voltage.'' A light bulb would be a typical case in point.] The volt is actually such a familiar unit that eletric field is usually measured in the derivative unit, volts per meter (V/m). It really is time now to begin discussing units - what are those constants kE and kM, for instance? But first I have one last remark about potentials.
The electrostatic potential
is often referred to as
the SCALAR POTENTIAL, which immediately suggests that
there must be such a thing as a VECTOR POTENTIAL too.
Just so. The VECTOR POTENTIAL
is used to
calculate the magnetic field
but not quite
as simply as we get
from
.
In this
case we have to take the ``curl'' of
to get :
(17.16) |