The Efficiency Race: How do CdTe and CIGS Stack up?

>> Nov 17, 2010

First Solar may have all the manufacturing scale, but there is still a measure on which these technologies are still competing very closely: efficiency.  Higher efficiencies are huge because the same amount of glass & aluminum provides more power – and since modules are priced based on their power, that extra money goes straight to the bottom line of the manufacturer.

Bandgap background

To understand what will determine efficiency, we have to dive into physics for a moment.  I’ll keep it quick.  Photons from the sun come in a wide range of wavelengths – this is what gives us the color spectrum.

So the solar cells are tasked with absorbing that spectrum of light.  Ideally, they would absorb the entire spectrum – but in reality, there are a host of constraints (e.g. shading, reflection, and recombination) that reduce the amount that a cell can absorb.


CdTe and CIGS have been selected because their bandgap efficiency is very good, so a very thin layer can capture much of the sun’s energy.  This is where they get the name “thin film.”  (One interesting thing in the chart below: notice how the thinner CdS layer (which is physically in front of the CdTe) improves the cell efficiency.  This illustrates the shading phenomenon – just a small taste of what the folks at First Solar and Abound are working on…)

What is efficiency, anyway?

You might be asking what “10% efficiency” means.  It’s actually way simpler than you think.  “Full sunlight” (noon on a summer day), means that a square meter of earth at sea level is hit with 1,000 watts of energy.  A nice round number.  So to put it mathematically, a full sun is equal to 1kW / m^2.

Efficiency is therefore a measure of the amount of sunlight that a module can absorb at full sun.  A 10% efficient module that is exactly 1 square meter large would generate 100W in full sun (1,000W x 0.10).  Using real numbers: a First Solar module is 1.2m x 0.6m (0.72 square meters).  If it generates 80 watts at peak power, that module is 11.1% efficient (80W/(0.72 square meters*1000)).

The Debate

The efficiency race between these two technologies has been close for decades (see the chart below).  Both have a theoretically maximum efficiency of about 30%.  CIGS advocates brag that CIGS has the highest lab efficiency (19.9% efficient).  However, it was done using an intensely complex process: quadruple sublimation (essentially, evaporating four different components at the same time, at very precise levels).  This process was so complex, in fact, that no company is seriously trying to commercialize it.

CdTe has a lower champion cell, but it is much simpler to manufacture.  Its bandgap (1.4 eV) is almost perfectly tuned to capture the most sun with the least material.

[Again, a disclaimer: I used to work at a CdTe startup.]

So what do the companies have to say?  What is being produced out of real factories?  We can look at available datasheets to see the efficiencies promised:

Company Material Size Power Efficiency
First Solar CdTe 0.72 m^2 70W – 80W 9.7% – 11.1%
Nanosolar CIGS 2.0 m^2 160W – 220W 8.0% – 11.0%
Wurth CIGS 0.73 m^2 70W – 80W 9.6% – 11.0%
Solyndra CIGS 1.97 m^2 150W – 200W 7.6% – 10.2%
Stion CIGS 1.10 m^2 110W – 130W 10.0% – 11.8%


Pretty close, huh?  That’s why it’s still an open debate.  Physicists tend to predict that CIGS will eventually win – the lab efficiency is so much higher!  But manufacturers have a healthy respect for the simplicity of CdTe; First Solar may keep the thin-film efficiency crown for years to come, through their manufacturing prowess.  And only time will tell.

One last caveat on cell efficiency: don’t mistake cell efficiency for module efficiency.  Module efficiency is always lower – often by 10-20%.  (An analogy: cell efficiency is sort of like highway MPG, whereas module would be city MPG.)  There are a bunch of reasons for this difference: resistance in the module, mismatch across cells, or shading from the front electrodes.  Cell efficiency is still important – but module efficiency is what you’ll actually get in the real world.

Source: Renewable Energy

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