Conductivity Tensor: Problem 4.7 Purcell Analysis

psholtz
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Homework Statement



I'm working through Problem 4.7 in Purcell, on conductivity tensors.

We build a conductor by alternately stacking plates of tin and silver (differing conductivities). When we pass a current through this "composite" conductor, we will get a different value for the conductivity depending on whether we apply the current (a) parallel; or (b) perpendicular to the plates.

Let \sigma_1 designate the conductivity of the silver plate, and \sigma_2 designate the conductivity of the tin.

The silver plate is 100 angstrom thick, and the tin plate is 200 angstrom thick.

We are seeking the "ratio" of \sigma_{\perp} / \sigma_{\parallel}

Homework Equations



The important equation is the "microscopic" version of Ohm's Law:

\mathbf{J} = \sigma \mathbf{E}

The Attempt at a Solution



First let's derive a value for \sigma_{\perp}, which is to say, the conductivity we get when passing the current perpendicular to the plates. The current density must be the same in both regions (silver and tin). Because the conductivities of the metals differ, we must have a charge layer that builds up at the junction between the metal plates. In other words:

J_1 = J_2

\sigma_1 E_1 = \sigma_2 E_2

and since \sigma_1 > \sigma_2, we must have E_1 < E_2.

Let E_0 be the 'net" electric field driving the (uniform) current density in both regions (i.e., J_{net} = \sigma_{net} E_0 = \sigma_{\perp} E_0). We have:

E_1 = E_0 - E_{charge layer}

E_2 = E_0 + E_{charge layer}

from which we obtain:

\large{ E_0 = \frac{1}{2}(E_1 + E_2)}

\large{E_0 = \frac{J}{2}(\frac{1}{\sigma_1} + \frac{1}{\sigma_2})}

\large{E_0 = \frac{J}{2}( \frac{\sigma_1 + \sigma_2}{\sigma_1 \sigma_2} )}

\large{J = \frac{2 \sigma_1 \sigma_2}{\sigma_1 + \sigma_2} E_0 }

From which we conclude:

\sigma_{\perp} = \frac{2 \sigma_1 \sigma_2}{\sigma_1 + \sigma_2}

Note that if \sigma_1 = \sigma_2 = \sigma, we have:

\sigma_{\perp} = \frac{2 \sigma^2}{2 \sigma} = \sigma

which is the result we expect.

Now let's derive the "parallel" conductivity. Again, we will have a net "applied" electric field E_0 but this time, the applied field will produce two distinct current denstities in the respective metal layers. The "net" current density, the one we will use to calculate the "parallel" conductivity of the material, will be the vector sum of these two (in other words, there will be no net charge layer). We have:

J_1 = \sigma_1 E_0

J_2 = \sigma_2 E_0

Bearing in mind that the silver layer (sigma 1) is 100 ang thick, and the tin layer (sigma 2) is 200 ang thick, we have:

J_{total} = J_1 + J_2 = \frac{\sigma_1 + 2\sigma_2}{3} E_0

So that:

\sigma_{\parallel} = \frac{\sigma_1 + 2\sigma_2}{3}

Again, if \sigma_1 = \sigma_2 = \sigma, we have:

\sigma_{\parallel} = \frac{\sigma + 2\sigma}{3} = \sigma

which is the expected result.

The ratio we initially set out to calculate is thus:

\sigma_{\perp} / \sigma_{\parallel} = \frac{6 \sigma_1 \sigma_2}{(\sigma_1 + \sigma_2)(\sigma_1 + 2\sigma_2)}

If we suppose that \sigma_1 = k\sigma_2 this reduces to:

\sigma_{\perp} / \sigma_{\parallel} = \frac{6 k \sigma_2^2}{(k\sigma_2 + \sigma_2)(k\sigma_2 + 2\sigma_2)} = \frac{6 k \sigma_2^2}{(k + 1)(k + 2)\sigma_2^2}

\sigma_{\perp} / \sigma_{\parallel} = \frac{6k}{(k+1)(k+2)}

Taking k=7.2, we have:

\sigma_{\perp} / \sigma_{\parallel} = 0.573

However, the answer in the book is 0.457.

What am I doing wrong?
 
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Your $\sigma_\perp$ equation is wrong. It should be $\sigma_\perp = \frac{3 \sigma_Ag \sigma_sn}{\sigma_Sn + 2 \sigma_Ag}$.
 
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