Using a protein taken from nature, scientists have made artificial leaves that can harvest energy faster than natural ones, and the ultra-lightweight material opens up the possibility of wearable technology and paint-on solar cells.
For many years, scientists have been trying to learn new tricks from leaves, and now Dr Nicolas Plumeré from the Ruhr-University Bochum, in Germany, and his colleagues have finally succeeded in beating nature at its own game.
Backed by a European Union COST Action grant and the German Research Foundation, the researchers have developed a semi-artificial leaf that incorporates a protein found in real leaves and is responsible for transporting electrons during photosynthesis.
They isolated the protein from an algae found living in hot springs in Japan. But inserting the protein into their artificial leaf was no easy task.
‘This protein complex comes from the membrane of the algae which is a hydrophobic (water avoiding) environment,’ said Dr Plumeré. ‘We first needed to make it hydrophilic (water attracting) in order to dissolve it and mix it with the polymers we use. Once incorporated into the artificial leaf we then had to bring it back into a hydrophobic environment.’
The scientists found a way to flip the protein from hydrophilic to hydrophobic by altering the acidity of the environment, and in this way managed to incorporate it into their artificial leaf. Plumeré and his colleagues found that the artificial leaf transported electrons over seven times faster than a real leaf.
However, it is not just the speed of electron transfer that is causing excitement. ‘Unlike silicon, which is rigid and opaque, this new material is fully transparent and flexible. It can be applied like a paint, to produce a very thin layer,’ Dr Plumeré said. And its natural ingredients mean that it is less likely to be rejected by the body if incorporated into medical devices.
‘This new material is fully transparent and flexible.’
Dr Nicolas Plumeré, Ruhr-University Bochum, Germany
Dr Plumeré and his colleagues are exploring the possibility of using their semi-artificial leaf to power micro-sized medical devices, such as sensors implanted in contact lenses. ‘Such a device could monitor a person's tears and collect information on diabetes for example,’ he said.
In order to make this idea a reality, the semi-artificial leaf also needs to be low cost. Currently it takes one person more than two weeks to make just 10 milligrams – enough to make one square metre of semi-artificial leaf.
But if production was scaled up, he is confident that it would become cheap enough to incorporate into relatively short-lived products. ‘We envisage that it could be used in clothing. Rather than queuing for power sockets at the airport, you could charge your smartphone or laptop from a solar battery on the sleeve of your coat, as long as there is sunshine of course,’ he said.
Other European Union projects are also taking their inspiration from natural photosynthesis. The European Research Council’s PhotoCatH2ode project exploits the metabolism of a particular type of micro-algae which uses solar energy to split water into hydrogen and oxygen.
‘As far as the energetic aspect is concerned, the photosynthetic process is a fascinating example of efficiency, and highly attractive for the development of novel hydrogen production technologies,’ explained Dr Vincent Artero, from the Université Joseph Fourier in Grenoble, France.
Together with his colleagues, he aims to incorporate bio-inspired catalysts into their own version of a semi-artificial leaf, which could then be used to produce plentiful hydrogen as a renewable form of energy.
Using light as an energy source, photosynthetic microalgae can be used to produce products like biofuels and cosmetics. But algae grown in a reactor block out the light on which they feed. New reactor designs could solve this problem and help the industry move forward.
Thanks to rapid computing developments in the last decade and the miniaturisation of electronic components, people can, for example, track their movements and monitor their health in real time by wearing tiny computers. Researchers are now looking at how best to power these devices by turning to the user’s own body heat and working with garments, polka dots and know-how from the textile industry.
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