Notes for Lecture

Apr 5, 2000

Notes for Lecture Notes for Lecture #30

Electromagnetic wave guides

In order to understand the operation of a wave guide, we must first learn how electromagnetic waves behave in a dissipative medium. A plane wave solution to Maxwell's equations of the form:

E = E₀e^{ik [^(k)] ·r - i wt} and B =

^
k

×E₀ e^{ik [^(k)] ·r - i wt}

(1)

for the electric and magnetic fields, with the wave vector k satisfying the relation:

k² = w² me º R + i I.

(2)

We can determine the complex wavevector k_r + i k_i according to

k_r =

æ
ç
ç
ç
è

R²+I²

ö
÷
÷
÷
ø

1/2

and k_i =

æ
ç
ç
ç
è

R²+I²

-R

ö
÷
÷
÷
ø

1/2

(3)

The form of the frequency dependent constants R and I depend on the materials. For the Drude model at low frequency (Eq. 7.56), R = w² me_b and I = wms, for example. The value of k_i determines the rate of decay of the field amplitudes in the vicinity of the surface, with the skin depth given by d º 1/k_i. In the limit that I >> R, as in the case of a good conductor at low frequency, d » (2/(wms) )^1/2.

For an ïdeal" conductor I ® ¥, so that the fields are confined to the surface. Because of the field continuity conditions at the surface of the conductor, this means that, B_tangential ¹ 0 (because there can be a surface current), E_normal ¹ 0 (because there can be a surface charge), and B_normal = 0.

Suppose we construct a wave guide from an ïdeal" conductor, designating [^(z)] as the propagation direction. We will assume that the fields take the form:

E = E(x,y) e^ikz-iwt and B = B(x,y) e^ikz-iwt

(4)

inside the pipe, where now k and e are assumed to be real. Assuming that there are no sources inside the pipe, the fields there must satisfy Maxwell's equations (8.16) which expand to the following :

¶B_x

¶x

¶B_y

¶ y

+ i k B_z = 0.

(5)

¶E_x

¶x

¶E_y

¶ y

+ i k E_z = 0.

(6)

¶E_z

¶y

- i k E_y = i wB_x.

(7)

i k E_x -

¶E_z

¶x

= i wB_y.

(8)

¶E_y

¶x

¶E_x

¶ y

= i wB_z.

(9)

¶B_z

¶y

- i k B_y = -i mew E_x.

(10)

i k B_x -

¶B_z

¶x

= -i mew E_y.

(11)

¶B_y

¶x

¶B_x

¶ y

= -i mewE_z.

(12)

Combining Faraday's Law and Ampere's Law, we find that each field component must satisfy a two-dimensional Helmholz equation:

æ
ç
è

¶²

¶x²

¶²

¶ y²

- k² + mew²

ö
÷
ø

E_x(x,y) = 0,

(13)

with similar expressions for each of the other field components. For the rectangular wave guide discussed in Section 8.4 of your text a solution for a TE mode can have:

E_z(x,y) º 0 and B_z(x,y) = B₀ cos

æ
ç
è

m px

ö
÷
ø

cos

æ
ç
è

n p y

ö
÷
ø

(14)

with k² º k²_mn = mew² -[([(m p)/ a])² + ([(n p)/ b])²] . From this result and Maxwell's equations, we can determine the other field components. For example Eqs. (7-8) simplify to

B_x = -

E_y and B_y =

E_x.

(15)

These results can be used in Eqs. (10-11) to solve for the fields E_x and E_y and B_x and B_y:

E_x =

B_y =

-i w

k²-mew²

¶B_z

¶y

-iw

é
ê
ë

æ
ç
è

m p

ö
÷
ø

æ
ç
è

n p

ö
÷
ø

ù
ú
û

n p

B₀ cos

æ
ç
è

m px

ö
÷
ø

sin

æ
ç
è

n p y

ö
÷
ø

(16)

and

E_y = -

B_x =

i w

k²-mew²

¶B_z

¶x

i w

é
ê
ë

æ
ç
è

m p

ö
÷
ø

æ
ç
è

n p

ö
÷
ø

ù
ú
û

n p

B₀ sin

æ
ç
è

m px

ö
÷
ø

cos

æ
ç
è

n p y

ö
÷
ø

(17)

One can check this result to show that these results satisfy the boundary conditions. For example, E_tangential = 0 is satisfied since E_x(x,0) = E_x(x,b) = 0 and E_y(0,y) = E_y(a,y) = 0. This was made possible choosing ÑB_zû_surface·[^(n)] = 0, where [^(n)] denotes a unit normal vector pointing out of the wave guide surface.

File translated from T_EX by T_TH, version 2.20.
On 5 Apr 2000, 10:04.