Researchers in the US have built a new type of solar cell that emits
light as well as absorbs it, making it the most efficient
single-junction device ever developed. The efficiency of their prototype
cell allows it to convert 28.6% of the Sun's energy into electricity.
This is a considerable increase from the previously recorded highest
efficiency of 26.4%, which was achieved in 2010.
Scientists have known since 1961 that the absolute limit for
the amount of energy that can be harvested from sunlight hitting a
typical solar cell is about 33.5%. However, for almost five decades
researchers have been unable to come close to achieving this theoretical
efficiency. But now, Eli Yablonovitch and his graduate student Owen
Miller from the University of California, Berkeley have designed and
built a new type of solar cell that gets closer to that limit by
mimicking the behaviour of a light-emitting diode. That is to the say the
solar cell is highly capable of absorbing light as well as emitting it.
In fact, it is the controlled emission of light that has boosted the
efficiency.
The researchers have shown that the better a solar cell is at
emitting photons, the higher its voltage is and the greater its
efficiency. "[The result] is almost paradoxical and counterintuitive. It
can be quite confusing to grasp at first," says Yablonovitch, as he tells physicsworld.com
that he and his colleagues discovered the connection while trying to
resolve the large gap between the theoretical and achieved limits for
solar-cell efficiency.
Managing photons
The solution lay in a mathematical connection between absorption and
emission of light – a phenomenon better understood as "photon
management". Conventionally, photon management involves controlling the
photons incident on a solar cell so that a photon ejects as many
electrons as possible, thereby generating the maximum amount of electric
current. "But there is another aspect to photon management, in that we
manage not only the incident light, but also the emitted light. Emitted
photons sometimes get 'lost' within the cell, so what we do is make sure
those photons are emitted," explains Yablonovitch. In a conventional
solar cell, photons from the Sun hit a semiconductor material, knocking
electrons loose and allowing them to flow freely. But this process can
also generate new photons, in a process known as "luminescent emission".
As there is a fundamental thermodynamic link between absorption and
emission, designing solar cells to emit light causes an increase in the
voltage produced by the device.
The researchers' novel concept has been put into practice by a
company called Alta Devices, which was co-founded by Yablonovitch and
California Institute of Technology physicist Harry Atwater in 2007. The
firm was set up specifically to produce economic and high-energy solar
cells. The new prototype solar cell is made of gallium arsenide, a
material often used to make solar cells for satellites. The result is a
device that operates at 28.6% efficiency.
First to put into practice
While the theory of luminescent emission causing an increase in
voltage has been known for a while, it has never been put into
practice. "It is somewhat puzzling why it has never been used in the
field of solar-cell development until now. But a lack of certain
requirements might explain that," says Yablonovitch. He goes on to say that
solar cells are "grown" on substrates that are generally of poor
quality and act as "sinks" for the emitted luminescent photons, which
are then lost. The new cell made by Alta Devices is separated from the
substrate, which delivers a much better performance. "In fact, we
separate the substrates on which the cells are grown and then re-use
them. This not only helps with efficiency, but it also brings the cost
of producing our cells down, and so it is a key factor," says
Yablonovitch. He explains that the cells are still as thin (1 µm) as
traditional cells and so people are genuinely shocked to know the
devices have been developed cheaply using gallium arsenide. Alta Devices
is already producing the cells on an industrial scale, with samples
being shipped to customers.
Yablonovitch says
he hopes researchers will be able to use this technique to achieve
efficiencies close to 30% in the coming years. And given that the work
applies to all types of solar cells, the findings have implications
throughout the field.
The team will present its findings at the Conference on Lasers and
Electro Optics to be held in early May in California in the US.
The research is to be published in Journal of Photovoltaics.
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