Tyndall researchers seek artificial leaf
RENEW research team look to unlock the energy potential of water.
Researchers at Tyndall National Institute, Cork, are partnering with scientists from the United States and Belfast to unlock the energy potential in water by creating what amounts to an artificial leaf.
The project aims to use semiconductor materials and sunlight to isolate energy-laden hydrogen in water by replicating processes found in nature.
The €1 million initiative, entitled 'Research into Emerging Nanostructured Electrodes for the Splitting of Water' (RENEW), is led by Professor Martyn Pemble and Dr Paul Hurley at Tyndall, Professor Paul McIntyre at Stanford University and Professor Andrew Mills at Queen's University Belfast.
Borrowing from electronics, the researchers will first seek to create the optimum 'artificial leaf' using layers of semiconducting materials such as silicon. These would be water-resistant and used to ultimately create clean fuel by splitting the molecules of water into hydrogen and oxygen under natural conditions without any additional energy.
Stokes Professor of Materials Chemistry at Tyndall, Prof Pemble - one of four principal investigators for the project - explained: "The main focus for the project is a tiny, stacked arrangement of materials that is used for some transistors in the electronic industry. Previous work has shown that these structures can act as basic 'artificial leaves' for splitting water and the aim now is to make them more efficient."
Professor Pemble added: "Professor McIntyre has shown that if you put the right metal on the surface of a silicon stack and provide light, then you can get it to oxidise water to give oxygen. Then, on another electrode connected to it - perhaps a platinum wire - the electrons that we have gained can be used to reduce water, and this produces hydrogen. So it only requires the sunlight to fall on this attack of layers where the water oxidation takes place. Then, according to Prof Andrew Mills, who is an acknowledged expert on photocatalysis, 'the rest of the process is driven by the electrochemistry'."
While previous similar processes for harvesting hydrogen for fuel have required the use of additional energy, or have been heavily reliant on the presence of ultra-violet light, RENEW will focus on using natural light and will experiment with a range of semi-conducting materials. Key to the process will be creating an impenetrable top layer that can withstand water's corrosive effects, by a process known as atomic layer deposition.
Photo: The "RENEW" project research team that is aiming to unlock the energy in water molecules. From left: Dr Ian Povey (Tyndall), Adrian Walsh (Tyndall), Jan Kegel (Tyndall), Dr Karim Cherkaoui (Tyndall), Dr Paul Hurley (Tyndall), Dr Scott Monaghan (Tyndall), Prof Paul McIntyre (Stanford University), Prof Andrew Mills (Queen’s University Belfast) and Prof Martyn Pemble (Tyndall). Credit: Tyndall National Institute.
Business World - http://www.businessworld.ie/livenews.htm?a=3156782
Business and Leadership - http://www.businessandleadership.com/leadership/item/45377-tyndall-in-collaboration/
Optics - http://optics.org/news/5/4/4
SFI - http://www.sfi.ie/investments-achievements/research-showcase/energy-on-tap-from-water-%E2%80%93-just-add-light.html