Submersible solar cell promises water-splitting renewable fuel generation

Submersible solar cell promises water-splitting renewable fuel generation

Researchers at Stanford University (Stanford, CA) and Tyndall National Institute (Cork, Ireland) have developed a solar cell design that can be submerged in water to help produce clean, renewable fuel from 'water-splitting' chemical reactions.
By eeNews Europe

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In a paper published in Nature Materials, the researchers showed how a new design of submerged, water-resistant solar cell produces a record-breaking voltage, suggesting that it will be possible for the electricity needed to split water molecules into fuel components can be generated solely from sunlight.

The ‘artificial photosynthesis’ technology can be used to split water into its constituent elements of pure oxygen and hydrogen, where the hydrogen represents a clean fuel that produces only water when it is burned. The technology can also be used to produce methane (natural gas) and methanol from reactions involving hydrogen and carbon dioxide. With sunlight as a sole source of energy, water-splitting reactors could provide a renewable source of hydrogen, methane, and methanol, and potentially funnel CO2 into reactors for transformation into fuel instead of releasing it into the atmosphere.

The RENEW project (Research into Emerging Nanostructured Electrodes for the Splitting of Water) has brought scientists from Ireland, Northern Ireland, and the U.S. together to tackle the challenge of designing solar cells that do not corrode under water and produce enough voltage to split water molecules without an outside source of electricity. A breakthrough in the corrosion issue was achieved by Professor Paul McIntyre and colleagues at Stanford University in 2011, who added a thin layer of titanium dioxide to the anode part of the solar cell to protect its surface from water corrosion.

But this presented a problem. The thicker the protective layer, the less voltage generated by the silicon-based cell beneath. Dr Paul Hurley of Tyndall National Institute in Cork suggested an innovation that might boost the voltage, fabricated a prototype, and sent it to Stanford for testing, where the voltage-producing capacities of the new solar anode design exceeded all expectations.

"The holy grail of water-splitting using solar cells is that you put it into water, and just use solar energy to split the water molecules," says Dr Paul Hurley, one of the lead researchers at Tyndall National Institute. "The aim is to get hydrogen reliably without applying any voltage."

"However, when the protective titanium dioxide layer was added, it resulted in a reduction in the light induced voltage. At Tyndall, we suggested adding a new layer of silicon doped with an excess positive charge between the original silicon cell and the protective layer. The idea was to create just a little more photovoltage than achieved with one type of silicon, but when we sent it to Stanford for testing, they found it was much better, and in fact it broke the record for the voltage produced by this type of anode."

"Working in collaboration with Prof Paul McIntyre and Andrew Scheuermann at Stanford, we were able to figure out why the new structure worked, and how it allowed the protective layer to be made thicker without paying the penalty of less photovoltage," says Hurley. "The anode can now be improved for long-term stability and to achieve as much photovoltage as you can get from silicon, and the concept also applies to other semiconductors. At Tyndall, we are now examining different materials that can protect silicon, conduct electricity, and be transparent enough to transmit light".

As Dr Hurley notes, an important aspect of the project was bringing together researchers from different backgrounds who had new perspectives on the physics and chemistry of the water splitting devices, and it was this mix of different research areas that was central to the progress achieved through the U.S.-Ireland collaboration. Coming from a background of developing energy-efficient transistors, he recognized many similarities between the design of transistors in integrated circuits and the structures used in electrochemical solar devices.

While he emphasizes that the voltage produced from the new design (0.6 V) is not yet sufficient to split water, the record-breaking voltage opens the way for cells to be tested that use the new design principles. These could combine the silicon anode with an amorphous silicon absorbing layer into what is called a tandem cell structure, with the potential to produce sufficient voltage to split water with no externally applied voltage.

For more, see the paper in the journal Nature Materials: "Design principles for maximizing photovoltage in metal-oxide-protected water-splitting photoanodes."

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