https://arstechnica.com/science/2023/07/perovskite-silicon-solar-panels-hit-efficiencies-of-over-30/

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Split level --

Perovskite + silicon solar panels hit efficiencies of over 30%

The two-layer panels still suffer from rapid decay of performance,
though.

John Timmer - Jul 7, 2023 5:58 pm UTC

Images of rows of solar panels in a grassy area.
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In most industrialized countries, solar panels account for only a
quarter to a third of the overall cost of building a solar farm. All
the other expenses--additional hardware, financing, installation,
permitting, etc--make up the bulk of the cost. To make the most of all
these other costs, it makes sense to pay a bit more to install
efficient panels that convert more of the incoming light into
electricity.

Unfortunately, the cutting edge of silicon panels is already at about
25 percent efficiency, and there's no way to push the material past
29 percent. And there's an immense jump in price between those and
the sorts of specialized, hyper-efficient photovoltaic hardware we
use in space.

Those pricey panels have three layers of photovoltaic materials, each
tuned to a different wavelength of light. So to hit something in
between on the cost/efficiency scale, it makes sense to develop a
two-layer device. This week saw some progress in that regard, with
two separate reports of two-layer perovskite/silicon solar cells with
efficiencies of well above 30 percent. Right now, they don't last
long enough to be useful, but they may point the way toward
developing better materials.

Wearing layers

The idea behind two-layer--called tandem--photovoltaic devices is very
simple. The top layer should absorb high-energy photons and convert
them to electricity while remaining transparent to other wavelengths.
Then, the layer underneath it should absorb lower energy photons.
Silicon, which tends to have peak absorption toward the red end of
the spectrum, is a great candidate for the lower layer. That leaves
the question of what might make sense to put on top of it.

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Perovskites make an appealing candidate. They're an entire class of
materials that are defined by the structure of the crystals they can
form; they can be made from a huge variety of unrelated chemicals.
That has some considerable advantages since it means you can
potentially identify some very inexpensive source materials that can
combine into a perovskite crystal. Many perovskites will also readily
form from a solution of the raw materials, potentially allowing us to
put a photovoltaic perovskite coating on a huge range of hardware.

The big problem has been that a lot of these crystals aren't
especially stable and will break down into raw materials over time.
And that time can be as little as weeks to months for some of the
more promising materials. There has been some progress in extending
their lifespan, but we're still not at the point where it makes sense
to manufacture perovskite panels.

The other good thing about perovskites is that, by choosing the raw
materials carefully, you can tune the peak wavelength absorbed by the
resulting crystal. So you can pick a wavelength that pairs well with
silicon. And there have been a few demonstrations that tandem
perovskite/silicon cells work, but the efficiencies haven't been much
above what silicon can achieve on its own.

Page: 1 2 Next -

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85 with
 
John Timmer John is Ars Technica's science editor. He has a Bachelor
of Arts in Biochemistry from Columbia University, and a Ph.D. in
Molecular and Cell Biology from the University of California,
Berkeley. When physically separated from his keyboard, he tends to
seek out a bicycle, or a scenic location for communing with his
hiking boots.
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