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It seems that a solar cell is just a pn-junction with a relatively large
area, some defects and and some contacts, following relatively simple junction theory - as described
before? |
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No - so far we have only looked
at a large real pn-junction. A real solar cell that will end up on somebodies
rooftop is a bit more than that. If it is a standard 2007
Si bulk solar cell (SC),
it must meet the following criteria on top of being just a large pn-junction: |
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Processing
Time. A typical 12.5 cm x 12.5 cm bulk Si solar cell comes off a production line at the rate of
about 1 SC/s. |
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If its size is 150 cm2 = 1.5 · 10–2 m2,
the factory produces 1.5 · 10–2 · 3 600 · 24 · 365 = 4.73 · 105
m2 per year; good for about 7 · 107 Wp or 70 MWp.
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At at thickness of 300 µm you used up 45 m3 of Si or
about 105 t. At a kg price around (10 - 40) €/kg, this costs around (1 - 4) Mio € |
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Nevertheless, you still have a very small factory according to 2007 standards. Presently,
the first 1 GWp factories are being built. Whichever way you look at it, is simply means that process
time is even less than 1s per cell, that you process in large batches, i.e. many cells in parallel like in a furnace,
or you just have several factories in parallel. However way you look at a 1 GWp/a factory - this is tough,
man! |
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Cost
Decrease The productions costs of a solar cell must go down about 5 % - 7 % /year for the next
10 - 15 years. |
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If you can't meet this goal this, you close your factory and go bankrupt. There is no market
for solar cells per se, there is only a market for power plants on roof tops (or other easily available cheap areas) with
a well-defined price for the kWh produced. |
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The price in most countries is defined by politics and decreases with 5 % - 7 % per
year (in Germany it is the "Energieeinspeisegesetz" (EEG); presently emulated by many other
countries). If there is such a well-defined price decrease for energy, people are only willing to pay for a solar module
if its price decreases at the same rate. I you can't meet this goal, chances are that your competitors can - and that will
be the end of your business while they will roll
in money. |
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Efficiency
Increase The efficiency of your solar cells must go up by about 1 % (absolute) every 12 - 18
month before it might level out around h = 20 %. |
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There are h
» 20 % solar cells on the market right now (Sunpower Corp.), proving that you can get
efficiencies that high even in a (presently limited) mass production. If you competitor manages to get his efficiencies up and you don't - see above.
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All serious companies therefore are working very hard on improving efficiencies -while still
lowering costs. |
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Key Material Supply Your
solar cell will use up less of the key materials, especially Si, meaning it becomes thinner. |
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Not only does this save costs - there is simply not
enough Si around at present (2007), to make all the solar cells the market would buy. Saving on Si
thus makes a lot of sense. |
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If you can make your cell thinner, you can go farther with the Si you managed to buy.
However, you cells are mechanically less stable and tend to break more easily. |
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Business Growth Rates The
solar cell you make is just one of many solar cell made world-wide per year - and their number increases with about 30
% - 40 %. |
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You have exponential growth at an extremely high growth rate and what that means has been
described very briefly in the context of microelectronics in chapter
5.3 and in somewhat more detail in the link.
In fact, much of what has been stated (and meanwhile observed) in the microelectronic business will repeat itself with solar
energy, just more so (there will be far more money involved as soon as solar energy can be measure in % of the total
energy needs of the world). |
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Summing Up Be prepared for
some turbulent times in solar cell R&D and production! Watch some companies grow from nothing to Microsoft proportion
and watch some people getting rich very fast |
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Maybe on of those winners will be you? |
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Silicon Starting Material
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You either start with single crystalline Si, i.e., more or less regular
wafers, or with what is called multi-crystalline Si | |
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If you go for single crystalline Si, you do everything pretty much as
already described except for the following points.
- You cut your crystal into an almost square shape because you loose to much area in your module if you "fill"
it with round solar cells as made from regular wafers. So you must find the best compromise between wasting expensive single
crystal Si or module area. The picture shows somewhat different solutions obviously because of different wafer size.
- You try to stay cheap. You might use slightly dirtier Si for growing your crystal and you might grow them somewhat
faster allowing a few dislocations or other defects not acceptable for microelectronics.
- You cut your crystal into very thin wafers, as this as you can make it, say 250 µm (instead of (600 -
800) µm used for microelectronics).
- You do not produce wafers with a highly perfect and flat surface. You may just etch off the saw damage and leave it
that.
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There is nothing really new, so we will not go into any more detail here but take a slightly
closer look at multi-crystalline Si. | |
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Multi-crystalline Si is simply coarse-grained poly-Si but since
the name poly-Si is already taken, multi-crystalline
Si is what it is called. |
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The picture below shows an example. |
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Multi-crystalline Si is produce by casting and cutting. As raw Si you must use rather clean electronic grade Si coming straight
from the Siemens process. Now melt this poly-Si
it and cast it into a mold. That sounds easy but their are a few catches: |
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1. Melting point density anomaly.
Si belongs to the few material that do not contract upon crystallization but expands
- by a whopping 10 %! |
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Producing a sizeable lump of Si by simple casting would be equivalent of casting ice
(solid H2O) at very low temperatures, say 80 K. Pour you molten ice (= water) in a bucket kept
at 80 K and watch what will happen. A major explosion will happen! |
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If you just leave your bucket around at low temperature, the surfaces will cool down first
and start to crystallize. Liquid water then is trapped inside a solid and tremendous forces will develop as soon as it crystallizes
an tries to expand. |
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What we have to do is to keep the surface of the Si liquid and crystallize slowly from
the bottom only. The crystal forming then can expand upwards and everything will be well behaved. The catch, of course,
is that we need to control the temperature and the temperature gradients closely, taking
into account that a lot of crystallization energy is released that needs to be taken out of the system. No is not a serious
technical problem - except that solving it takes money and that you have to wait longer for your Si melt to crystallize
and cool down (more money). |
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2. Reactivity of Si. We have poured some
liquid Si into a mold, cooled it down properly without encountering problems, and now want to take it out of the mold and
reuse the mold for the next batch. |
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The problem now is that your Si is firmly bounded to the walls of your mold if didn't
take proper precautions. In chemistry circles, Si is known as an universal
solvent because everything dissolves in liquid Si and thus sticks to the solidified Si in a major
way. |
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Of course, you can cut your Si ingot free, destroying the mold; all that takes is a
lot money for molds. this is obviously not a good idea. |
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A good idea is to use some "grease" that squeezes between the Si and the
old (and covers the Si surface) because it lowers the surface tensions of the system. |
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In other words, use a liquid encapsulation
technique - we already encountered this trick when we looked at the growth of III-V single crystals. |
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Now we encounter a new twist to an old technique: As far as casting Si is concerned,
everything from now on is top secret. Exactly how is to done has never been fully disclosed, so we will not belabor this
point anymore. The picture below shows how it is done in reality |
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The yellow patches hiding something have been placed by the source. What you see is the solidified
white "grease" and a sizeable chunk of Si in the 4th picture. Now we can cast and reuse the mold, but we are still left with a problem. |
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3. Cleanliness and Structure. We don't just want any big chunk of Si,
we want it to be multi-crystalline , meaning coarse- grained, and we certainly don't
want it any dirtier that the raw Si we poured into the mold. |
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So we have to make damned sure that the liquid Si - which, after all, is an universal
solvent - doesn't pick up some dirt from its surrounding. |
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We also have to make sure that crystallization produces big grains in some columnar arrangement (why we need this we will see right below). This brings
us back to an optimized temperature control and some secret issues I can't tell you concerning casting Si. |
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Now we are done. If you actually could obaibn some poly-Si, that is. The
solar energy business right now (2007 /08) is having a supply-side
crisis; there just isn't enough electronic grade Si around for everybody. You should have some vague idea by
now, why it took >10 years and a lot of work and money to come up with an industrial casting process that meets
all requirements (including costs). |
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All that's left to do is to cut the big block of Si into very thin, standard-sized,
square, multi-crystalline Si wafers, taking care that grain boundaries are always at right angles to the surface. |
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Cutting Silicon Ingots into Wafers
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Why is it important to have no grain boundaries running parallel to the wafer
surface? |
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Because grain boundaries are always efficient recombination centers and thus
screen minorities "below" from making to the the front side side contacts and take out minority carriers from
above that happen to come by. |
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If the grain boundaries are at more or less right angles to the surface of the wafer, they
are still bad but far less so then at 90o. |
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So we first cut our huge 300 kg ingot into square columns as indicated,
taking care to cut off the "dirty" (= reddish) surface-near regions; especially the bottom regions, where grain
nucleation started and we have fine-crystalline Si, and the top region, where all the dirt with low segregation coefficient will be found. This we do with
a big diamond-blade saw. |
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The columns left have the right wafer size and the grain boundaries inside all are more or
less at right angles to the major axis if our casting process was OK. |
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All we need to do now is to cut the column into very thin wafers (about 250
µm at present (2008)), making sure that the cutting grooves are very thin in order to minimize cutting losses. |
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Easy? - No, very difficult. In fact, a new process tool needed to be invented, the industrial-scale,
extremely precise wire saw. A very fine but very strong closed wire loop runs around the Si column many times, moving
fast, under high mechanical tension, and in an abrasive slurry. |
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In essence, its like a gigantic egg cutter with moving wires, just a bit more expensive. Cutting
off the joke: the Si multi-wire saw, cutting fast, in parallel, and with very high precision, is an essential piece
of equipment for multi-crystalline Si solar cells and you will thus not find much information about process details floating around.
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Just in case you didn't notice: We now have two special
semiconductor technologies here that originated from solar cell technology: casting and wire-saw cutting. |
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In fact, cutting Si with wire saws is now moving into the wafer business for microelectronics,
too. |
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What we have no are square slices or wafers of multi-crystalline Si, about
250 µm - 300 µm thick and up to (150 × 150) mm2 in lateral size;.. And, yes,
you're right - they fracture very easily. |
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Right after cutting, the surface of the multi-crystalline wafers is "destroyed";
or more precisely, on both sides are layers full of "saw-damage" that are electronically "dead". The
thickness of these layers scales with the size of the hard grains in the abrasive slurry and thus will be in the range of
several µm. |
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This surface damage must be removed before we can start to make a solar cell. Fortunately
this is easy if, once more, something of a black art: Certain chemicals attack and dissolve "damaged Si"
far faster than perfect Si (CMP relies on this!). So all we have to do is to put a batch of wafers
in a chemical tank for a while. |
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Since we have a batch process with, say, 100 wafers,
we can allow a process time of » 100 s and still meet our goal of 1 Solar cell per second. |
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With the "over-etched" wafers we can now start solar cell production |
© H. Föll (Semiconductor Technology - Script)
