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We will just give a brief look at some especially important or useful non-metallic conductors: |
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Conducting
Polymers |
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That polymers, usually associated with insulators, can be very good conductors
was a quite unexpected discovery some 20 years ago (Noble prize 2001). They always need some "doping" with ionic components, however. |
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The resistivity can be exceedingly low. e.g. for Iodine
(I) doped poly-acethylene (pAc) we may have.
r
£ 6,7 mWcm. |
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Or in other words: If you divide by the density for some figure
of merit, it beats everything else, since
{r/density} (pAc) > {r/density} (Na)! |
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More typical, however, are resistivities around (10 .... 1000) mWcm. |
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The conduction mechanism is along –C=C–C=C–C= chains, it is not yet
totally clear. In fact, the first question is why this kind of chain is not generally
highly conducting. Use the link for the answer. |
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The conductivity is strongly dependent on "doping" (in the % range!) with ions, and on
many other parameters, the link gives an example. |
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So do not confuse this with the doping of semiconductors, where we typically add far less than 1 % of a dopant!
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A new object of hot contemporary research are now semiconducting polymers which have been discovered about 10 years ago. |
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Transparent
conductors |
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Indium Tin Oxide (ITO) (including some variations) is the only really usable transparent
conductor with reasonable conductivity (around 1 Wcm)! It consists of SnO2
doped with In2O3. |
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ITO is technically very important,
especially for:
- flat panel displays, e.g. LCDs .
- solar cells.
- research (e.g. for the electrical measurements of light-induced
phenomena). |
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ITO is one example of conducting oxides, others are TiO, NiO, or ZnO.
The field is growing rapidly and known as " TCO" = Transparent Conducting Oxides |
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If you can find a transparent conductor much better than ITO (which leaves
a lot to be desired), you may not get the Nobel prize, but you will become a rich person rather quickly. |
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Since In is rare, and the demand is exploding since the advent of LCDs, you
also would be a rich person of you invested in In some years ago. |
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Specialities : Intermetallics,
Silicides, Nitrides etc. |
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Silicides, i.e. metal - silicon compounds, are
important for microelectronics (ME)
technology, but also in some more mundane applications, e.g. in heating elements. Some resistivity examples for silicides: |
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| Silicide | MoSi2 |
TaSi2 | TiSi2 |
CoSi2 | NiSi2 |
PtSi | Pd2Si |
| r ( mWcm) |
40 ...100 | 38...50 | 13..16 |
10...18 | » 50 |
28...35 | 30...35 |
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It looks like the winner is CoSi2. Yes, but it is difficult to handle and
was only introduced more recently, like NiSi2. In the earlier days (and at present) the other silicides
given above were (and still are) used. |
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Some more examples of special conductors
which find uses out there: |
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| Material | HfN | TiN |
TiC | TiB2 | C (Graphite) |
| r
(mWcm) | 30...100 |
40...150 | ca. 100 | 6 ...10 |
1000 |
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Why do we need those "exotic" materials?.
There are two general reasons: |
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1. Because, if just one specific requirement
exists for your application that is not met by common materials, you simply have no choice.
For example, if you need a conductor usable at 3000 K - you take graphite. No
other choice. It's as simple as that. |
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2. Because many requirements must be met simultaneously. Consider e.g. Al for integrated circuits - there are plenty of important
requirements; see the link. Since no
material meets all of many requirements, an optimization process for finding an optimum
material is needed. |
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Al won the race for chip metallization for many years, but now is crowded out by Cu,
because in some figure of merit the importance of low resistivity in the list of requirements is much larger now than it
was in the past. It essentially overwhelms almost all other concerns (if there would
not be an almost, we would have Ag!). |
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© H. Föll (Electronic Materials - Script)
