- Electromagnetics I
- Ch 5: Electrostatics
- Loc 5.18
- Electromagnetics I
- Ch 5
- Loc 5.18
Boundary Conditions on the Electric Flux Density (D)
In this section, we derive boundary conditions on the electric flux density
. The considerations are quite similar to those encountered in the development of boundary conditions on the electric field intensity (
) in Section 5.17, so the reader may find it useful to review that section before attempting this section. This section also assumes familiarity with the concepts of electric flux, electric flux density, and Gauss’ Law; for a refresher, Sections 2.4 and 5.5 are suggested.
To begin, consider a region at which two otherwise-homogeneous media meet at an interface defined by the mathematical surface
, as shown in Figure 5.18.1. Let one of these regions be a perfect electrical conductor (PEC).
In Section 5.17, we established that the tangential component of the electric field must be zero, and therefore, the electric field is directed entirely in the direction perpendicular to the surface. We further know that the electric field within the conductor is identically zero. Therefore,
at any point on
is entirely in the direction perpendicular to the surface and pointing into the non-conducting medium. However, it is also possible to determine the magnitude of
. We shall demonstrate in this section that
At the surface of a perfect conductor, the magnitude of D is equal to the surface charge density
(units of C/m
) at that point.
The following equation expresses precisely the same idea, but includes the calculation of the perpendicular component as part of the statement:
is the normal to
pointing into the non-conducting region. (Note that the orientation of
is now important; we have assumed
points into region 1, and we must now stick with this choice.) Before proceeding with the derivation, it may be useful to note that this result is not surprising. The very definition of electric flux (Section 2.4) indicates that
should correspond in the same way to a surface charge density. However, we can show this rigorously, and in the process we can generalize this result to the more-general case in which neither of the two materials are PEC.
Let the surface of integration
take the form of closed cylinder centered at a point on the interface and for which the flat ends are parallel to the surface and perpendicular to
. Let the radius of this cylinder be aa, and let the length of the cylinder be
. From Gauss’ Law we have
where the “top” and “bottom” are in Regions 1 and 2, respectively, and
is the charge enclosed
. Now let us reduce
together while (1) maintaining a constant ratio
and (2) keeping
, the area of the side can be made negligible relative to the area of the top and bottom. Then as
we are left with
As the area of the top and bottom sides become infinitesimal, the variation in
over these areas becomes negligible. Now we have simply:
are the electric flux density vectors in medium 1 and medium 2, respectively, and
is the area of the top and bottom sides. The above expression can be rewritten
Note that the left side of the equation must represent a actual, physical surface charge; this is apparent from dimensional analysis and the fact that
is now infinitesimally small. Therefore:
where, as noted above,
points into region 1.
Any discontinuity in the normal component of the electric flux density across the boundary between two material regions is equal to the surface charge.
Now let us verify that this is consistent with our preliminary finding, in which Region 2 was a PEC. In that case
, so we see that Equation 5.18.1 is satisfied, as expected. If neither Region 1 nor Region 2 is PEC and there is no surface charge on the interface, then we find
In the absence of surface charge, the normal component of the electric flux density must be continuous across the boundary.
Finally, we note that since
, Equation 5.18.5 implies the following boundary condition on
are the permittivities in Regions 1 and 2, respectively. The above equation illustrates one reason why we sometimes prefer the “flux” interpretation of the electric field to the “field intensity” interpretation of the electric field.
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