Unleashing Perovskites’
Potential for Solar Cells
New results show how varying the recipe could bring these materials closer to commercialization.
By David L. Chandler | MIT News Office
New results show how varying the recipe could bring these materials closer to commercialization.
By David L. Chandler | MIT News Office
February 7, 2019 -- Perovskites — a broad category of
compounds that share a certain crystal structure — have attracted a great deal
of attention as potential new solar-cell materials because of their low cost,
flexibility, and relatively easy manufacturing process. But much remains
unknown about the details of their structure and the effects of substituting
different metals or other elements within the material.
Conventional solar cells made of
silicon must be processed at temperatures above 1,400 degrees Celsius, using
expensive equipment that limits their potential for production scaleup. In
contrast, perovskites can be processed in a liquid solution at temperatures as
low as 100 degrees, using inexpensive equipment. What’s more, perovskites can
be deposited on a variety of substrates, including flexible plastics, enabling
a variety of new uses that would be impossible with thicker, stiffer silicon
wafers.
Now, researchers have been able to
decipher a key aspect of the behavior of perovskites made with different
formulations: With certain additives there is a kind of “sweet spot” where
greater amounts will enhance performance and beyond which further amounts begin
to degrade it. The findings are detailed this week in the journal Science,
in a paper by former MIT postdoc Juan-Pablo Correa-Baena, MIT professors Tonio
Buonassisi and Moungi Bawendi, and 18 others at MIT, the University
of California at San Diego
Perovskites are a family of
compounds that share a three-part crystal structure. Each part can be made from
any of a number of different elements or compounds — leading to a very broad
range of possible formulations. Buonassisi compares designing a new perovskite
to ordering from a menu, picking one (or more) from each of column A, column B,
and (by convention) column X. “You can mix and match,” he says, but until now
all the variations could only be studied by trial and error, since researchers
had no basic understanding of what was going on in the material.
In previous research by a team from
the Swiss École Polytechnique Fédérale de Lausanne, in which Correa-Baena
participated, had found that adding certain alkali metals to the perovskite mix
could improve the material’s efficiency at converting solar energy to
electricity, from about 19 percent to about 22 percent. But at the time there
was no explanation for this improvement, and no understanding of exactly what
these metals were doing inside the compound. “Very little was known about how
the microstructure affects the performance,” Buonassisi says.
Now, detailed mapping using
high-resolution synchrotron nano-X-ray fluorescence measurements, which can
probe the material with a beam just one-thousandth the width of a hair, has
revealed the details of the process, with potential clues for how to improve
the material’s performance even further.
It turns out that adding these
alkali metals, such as cesium or rubidium, to the perovskite compound helps
some of the other constituents to mix together more smoothly. As the team
describes it, these additives help to “homogenize” the mixture, making it conduct
electricity more easily and thus improving its efficiency as a solar cell. But,
they found, that only works up to a certain point. Beyond a certain
concentration, these added metals clump together, forming regions that
interfere with the material’s conductivity and partly counteract the initial
advantage. In between, for any given formulation of these complex compounds, is
the sweet spot that provides the best performance, they found.
“It’s a big finding,” says
Correa-Baena, who in January became an assistant professor of materials science
and engineering at Georgia Tech. What the researchers found, after about three
years of work at MIT and with collaborators at UCSD, was “what happens when you
add those alkali metals, and why the performance improves.” They were able to
directly observe the changes in the composition of the material, and reveal,
among other things, these countervailing effects of homogenizing and clumping.
“The idea is that, based on these
findings, we now know we should be looking into similar systems, in terms of
adding alkali metals or other metals,” or varying other parts of the recipe,
Correa-Baena says. While perovskites can have major benefits over conventional
silicon solar cells, especially in terms of the low cost of setting up
factories to produce them, they still require further work to boost their
overall efficiency and improve their longevity, which lags significantly behind
that of silicon cells.
Although the researchers have
clarified the structural changes that take place in the perovskite material
when adding different metals, and the resulting changes in performance, “we
still don’t understand the chemistry behind this,” Correa-Baena says. That’s
the subject of ongoing research by the team. The theoretical maximum efficiency
of these perovskite solar cells is about 31 percent, according to Correa-Baena,
and the best performance to date is around 23 percent, so there remains a
significant margin for potential improvement.
Although it may take years for
perovskites to realize their full potential, at least two companies are already
in the process of setting up production lines, and they expect to begin selling
their first modules within the next year or so. Some of these are small,
transparent and colorful solar cells designed to be integrated into a
building’s façade. “It’s already happening,” Correa-Baena says, “but there’s
still work to do in making these more durable.”
Once issues of large-scale
manufacturability, efficiency, and durability are addressed, Buonassisi says,
perovskites could become a major player in the renewable energy industry. “If
they succeed in making sustainable, high-efficiency modules while preserving
the low cost of the manufacturing, that could be game-changing,” he says. “It
could allow expansion of solar power much faster than we’ve seen.”
Perovskite solar cells “are now
primary candidates for commercialization. Thus, providing deeper insights, as
done in this work, contributes to future development,” says Michael Saliba, a
senior researcher on the physics of soft matter at the University
of Fribourg , Switzerland
Saliba adds, “This is great work
that is shedding light on some of the most investigated materials. The use of
synchrotron-based, novel techniques in combination with novel material
engineering is of the highest quality, and is deserving of appearing in such a
high-ranking journal.” He adds that work in this field “is rapidly progressing.
Thus, having more detailed knowledge will be important for addressing future
engineering challenges.”
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