NTU
Assoc Prof Annalisa Bruno seeing through the ultrathin perovskite solar cell
which is just 10 nanometers. Credit: Nanyang Technological University
Imagine
a car whose windows and sunroof can help top up its battery while parked under
the sun, or a pair of smart glasses whose lenses can harvest light to power
built-in electronics.
Such applications could become more
feasible with a new type of ultrathin transparent solar cell developed by
scientists from Nanyang Technological University, Singapore (NTU Singapore).
Led by Associate Professor Annalisa
Bruno, the NTU researchers created perovskite solar cells that are about 10,000
times thinner than a strand of human hair and around 50 times thinner than
conventional perovskite solar cells.
Despite their thinness, the devices
achieved some of the highest power conversion efficiencies reported for
ultrathin perovskite solar cells to date.
Published in the journal ACS Energy Letters, their
findings could pave the
way for solar cells that can be integrated into buildings, vehicles and
wearable devices without significantly changing their appearance.
Because the new solar cells are
semi-transparent and color-neutral, they could potentially be incorporated into
windows and façades without significantly changing how a building looks.
NTU
research fellow Dr Daniela De Luca examining a prototype ultrathin perovskite
solar cell in the vacuum chamber in the lab. Credit: Nanyang Technological
University
"The built environment
accounts for roughly 40% of global energy consumption, so technologies that
seamlessly convert buildings' surfaces into power-generating assets are gaining
urgency," said Assoc Prof Bruno, who is from NTU's School of Physical and
Mathematical Sciences and School of Materials Science and Engineering.
"Our perovskite solar cells
offer distinct advantages as they can be manufactured using simple processes at
relatively low temperatures. They can also be tuned to absorb specific
wavelengths while remaining transparent, and could potentially be scaled over
large areas, reducing their carbon footprint," added Prof Bruno, who is
also Cluster Director, Renewables & Low-Carbon Solutions and Energy
Storage, Energy Research Institute at NTU.
Unlike conventional silicon solar
cells, these perovskite-based devices are capable of generating electricity
even under indirect sunlight and diffuse light conditions. This makes it
particularly suited for Singapore's urban environment, where vertical building
surfaces and frequent cloud cover often limit direct solar exposure.
As an example, if the technology
were scaled up while maintaining similar performance, large glass façades could
be transformed into active surfaces for solar power generation.
Preliminary estimates suggest that
a deployment across a major glass-fronted building, such as an office tower at
Raffles Place or Marina Bay, could theoretically generate several hundred
megawatt-hours of electricity annually.
Depending on the usable glass area
and building orientation, this level of energy generation would be equivalent
to the annual electricity consumption of about 100 four-room HDB flats.
Manufacturing near-invisible solar cells
Perovskite solar cells are made up
of several layers, including a semiconductor layer that absorbs sunlight and
converts it into electricity.
To make the ultrathin cells, the
NTU team used an industrially compatible method known as thermal evaporation. In this process, source materials are heated in a
vacuum chamber until they evaporate. The vapor then settles on a surface, where
it forms a thin film.
The method allows very thin and
uniform perovskite layers to be deposited over large areas. It also avoids the
use of toxic solvents and helps reduce defects in the solar cells, improving
their ability to convert light into electricity.
By adjusting the process, the
researchers were able to control the thickness of the perovskite layer and
create both opaque and semi-transparent devices.
The team believes this is the first
time ultrathin perovskite solar cells have been made entirely using
vacuum-based processes. This could make the technology more suitable for
large-scale industrial production in the future.
Using the technique, the
researchers produced ultrathin perovskite absorber layers down to 10 nanometers
while retaining useful solar-cell performance.
In opaque devices, the cells
achieved power conversion efficiencies of about 7%, 11% and 12% for perovskite
layers measuring 10, 30 and 60 nanometers respectively.
A semi-transparent cell with a 60-nanometer-thin perovskite layer
allowed about 41% of visible light to pass through, while converting sunlight
into electricity at 7.6% efficiency.
The researchers said this is among
the best reported performances for semi-transparent perovskite solar cells made
with similar materials.
This will allow daylight to pass
through while still generating a useful amount of electricity, which is
important for applications such as solar windows, glass façades and tinted
building surfaces.
First author of the paper, Dr. Luke
White, a former Ph.D. student at the Energy Research Institute at NTU, the
School of Physical and Mathematical Sciences, and the School of Materials
Science and Engineering, said, "By precisely controlling thermal
evaporation, we are able to adjust the transparency of the solar cells. This opens up
new possibilities for sustainable architecture, such as tinted windows that
generate electricity."
Giving an independent comment,
Professor Sam Stranks, Professor of Energy Materials and Optoelectronics,
Department of Chemical Engineering and Biotechnology, University of Cambridge,
said, "This approach offers a high level of control over film thickness
and uniformity, which will be needed if semi-transparent solar cells are to
move towards larger-area applications."
"Semi-transparent perovskite
solar cells are an exciting route to harvesting energy from surfaces that are
difficult to use with conventional silicon panels, such as windows, façades and
lightweight electronics.
"The results reported here
show a promising balance between transparency and power generation in very thin
devices, while the next critical tests will be long-term stability, durability
and performance over larger areas."
Powering sustainable cities
Prof Bruno is a pioneer in the
field of perovskite solar cells. Her earlier work on thermally evaporated
perovskite solar cells has been scaled up, advancing the field of perovskite
solar cells and paving the way for industry adoption.
Her innovations are supported by
the NTU Innovation and Entrepreneurship initiative, which helps research teams
accelerate and translate promising ideas from laboratories to
commercialization.
A patent for the development of
the ultrathin perovskite
films in a
novel structure has been filed through NTUitive, the University's innovation
and enterprise company.
The researchers are now in talks
with companies to validate and standardize the thermal evaporation process used
in this study. They will also work to improve the long-term stability,
durability and large-area performance of the perovskite solar cells before they
can be commercially deployed.
As cities become denser and
electricity demand grows, buildings are increasingly being seen not just as
energy consumers, but as potential sources of clean energy.
Solar panels are already widely
used on rooftops. But the vertical surfaces of buildings, including windows and
glass façades, remain largely untapped.
Their breakthrough marks an important step towards transparent solar cells that can be integrated into everyday surfaces, from building windows to vehicles and wearable electronics, helping cities generate more clean energy without requiring additional land.
Provided by Nanyang Technological University
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