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First Task: Derive numbers for the mobility µ. |
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First we need typical conductivities and electron densities in metals,
which we can take from the table in the link. |
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At the same time we expand the table a bit |
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| Material |
r [W cm] |
s [W–1 cm–1] |
Density d × 103 [kg m–3] |
Atomic weight w
[× 1u = 1,66 · 10–27 kg] |
n = d/w
[m–3] |
| Silver Ag |
1,6·10–6 |
6.2·105 | 10,49 |
107,9 | 5,85 · 1028 |
| Copper Cu |
1,7·10–6 |
5.9·105 | 8,92 |
63,5 | 8,46 · 1028 |
| Lead Pb |
21·10–6 |
4.8·104 | 11,34 |
207,2 | 3,3 · 1028 |
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For the mobility µ we have the
equation |
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With q = elementary charge = 1,60 10–19 C
we obtain, for example for µAg |
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| µ | Ag = |
6,2 · 105
1,6 · 10–19 · 5,85 · 1028
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m3
C · W · cm |
= | 66,2 | |
cm2
C · W |
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The unit is a bit strange, but rembering that [C] = [A · s] and [W] = [V/A], we obtain |
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| µAg | = | 66,2
| | cm2
Vs |
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| | | µCu
| = | 43.6 | |
cm2
Vs |
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| µPb | = | 9,1 |
| cm2
Vs |
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Second Task: Derive numbers for the drift velocity vD by
considering a reasonable field strength. |
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The mobility µ
was defined as |
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So what is a reasonable field strength in a metal? |
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Easy. Consider a cube with side lengt l = 1 cm. Its resistance
R is given by |
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A Cu or Ag cube thus would have a resistance of about 1,5 ·10–6
W.
Applying a voltage of 1 V, or equivalently a field strength of 1 V/cm thus produces a current of I
= U/R
» 650 000 A or a current density j = 650 000 A/cm2 |
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That seems to be an awfully large current. Yes, but it is the kind of current
density encountered in integrated circuits! Think about it! |
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Nevertheless, the wires in your house carry at most about 30 A (above
that the fuse blows) with a cross section of about 1 mm2; so a reasonable current density is 3000 A/cm2,
which we will get for about U = 1,5 ·10–6
W · 3000 A = 4,5 mV. |
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For a rough estimate we then take a field strength of 5 mV/cm and a mobility
of 50 cm2/Vs and obtain |
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| vD | = |
50 · 5 | |
mV · cm2
cm · V · s |
= 0,25 | cm
s |
= 2,5 | mm
s |
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That should come as some surprise! The electrons only have to move v e r y s
l o w l y on average in the current direction (or rather, due to sign conventions,
against it). |
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Is that true, or did we make a mistake? |
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It is true! However, it does not
mean, that electrons will not run around like crazy inside the crystal, at very high speeds. It only means that their net movement in current anti-direction is very slow. |
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Think of an single fly in a fly swarm. Even better read the
module that discusses this analogy in detail. The flies are flying around at high speed like crazy - but the fly swarm
is not going anywhere as long as it stays in place. There is then no drift velocity and no net fly current! |
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© H. Föll (Advanced Materials B, part 1 - script)
With frame
Averaging Vectors