A peel-off patterning technique could enable more fragile organic semiconductors to be manufactured into semitransparent solar panels at scale
From:
University of Michigan
July 19, 2022 -- In an important step toward
bringing transparent solar cells to home windows, researchers at the University
of Michigan have developed a way to manufacture their highly efficient and
semitransparent solar cells.
"In principle, we
can now scale semitransparent organic solar cells to two meters by two meters,
which brings our windows much closer to reality," said Stephen Forrest,
the Peter A. Franken Distinguished University Professor of Electrical
Engineering and corresponding author of a study published in Joule.
Traditional
silicon-based solar cells are completely opaque, which works for solar farms
and roofs but would defeat the purpose of windows. However, organic solar
cells, in which the light absorber is a kind of plastic, can be transparent.
Organic solar cells
have lagged behind their silicon-based cousins for energy-producing purposes
due to engineering challenges such as low efficiency and short lifespans, but
recent work out of Forrest's lab has achieved record efficiencies of 10% and
estimated lifetimes of up to 30 years.
So the team has turned
its attention to making transparent solar cells manufacturable. A significant
challenge is creating the micron-scale electrical connections between
individual cells that comprise the solar module. Conventional methods that use
lasers to pattern the cells can easily damage the organic light absorbers.
Instead, the team
developed a multistep peel-off patterning method that achieved micron-scale
resolution. They deposited thin films of plastic and patterned them into
extremely thin strips. Then, they set down the organic and metal layers. Next,
they peeled off the strips, creating very fine electrical interconnections
between the cells.
The group connected
eight semitransparent solar cells, each 4 cm x 0.4 cm and separated by
200µm-wide interconnections, to create a single 13 cm2 module.
The power conversion efficiency of 7.3% was approximately 10% less than for the
individual solar cells in the module. This small efficiency loss does not
increase with the size of the module; hence, similar efficiencies are expected
for meter-scale panels as well. With a transparency nearing 50% and a greenish
tint, the cells are suitable for use in commercial windows. Higher
transparencies that are likely preferred for the residential market are easily
achieved by this same technology.
"It is now time to
get industry involved to turn this technology into affordable
applications," said Xinjing Huang, U-M doctoral student in applied physics
and first author on the published research.
Eventually, the
flexible solar cell panel will be sandwiched between two window panes. The goal
for these energy-generating window films is to be about 50% transparent with
10%-15% efficiency. Forrest believes this can be achieved within a couple
years.
"The research we
are doing is derisking the technology so that manufacturers can make the
investments needed to enter large scale production," Forrest said.
The technique can also
be generalized to other organic electronic devices, he says. And in fact, his
group is already applying it to OLEDs for white lighting.
The University of
Michigan has applied for patent protection and is seeking partners to bring the
technology to market.
Forrest is also the
Paul G. Goebel Professor of Engineering and professor of electrical and
computer engineering, materials science and engineering, physics and applied
physics. Co-authors Huang and former doctoral student Dejiu Fan (PhD EE 2020)
designed and conducted the experiments. Co-author and assistant research
scientist Yongxi Li assisted in the fabrication of the devices, which was
accomplished in the Lurie Nanofabrication Facility.
The research was
supported primarily by the U.S. Department of Energy. Additional support was
provided by Universal Display Corporation. Forrest and U-M have a financial
interest in Universal Display Corp.
https://www.sciencedaily.com/releases/2022/07/220719113406.htm
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