News Article
Multifunctional GaN could purify water and kill superbugs
Apart from slashing electricity consumption, gallium nitride LEDs have other potential uses
In the UK, lighting consumes over a fifth of all the electricity generated at power stations, and GaN LEDs have the potential to reduce this figure by at least 50 percent and possibly by 75 percent.
A revolution in lighting is under way. Thanks to advances in the technology, efficiency and cost of LEDs, these devices are ready to take over in the very near future from conventional forms of incandescent lighting.
The potential energy savings are huge: statistics from the US Department of Energy estimate that, by 2025, solid-state lighting such as LEDs could reduce the global amount of electricity used for lighting by 50 percent.
In the US alone, 258 million metric tons of carbon emission could be eliminated, alleviating the need for 133 new power stations, and result in cumulative financial savings of over a hundred billion dollars.
At the forefront of research underpinning this new lighting paradigm is a focus on the semiconductor gallium nitride (GaN) at the Cambridge Centre for Gallium Nitride in the Department of Materials Science and Metallurgy.
Why use GaN for LEDs?
LEDs based on GaN, which emits brilliant light when electricity is passed through it, are extremely energy efficient and long lasting. Traditional incandescent light bulbs are only 5 percent efficient at converting the electricity they consume into light, and, although low-energy light bulbs are 20 percent efficient, they contain hazardous mercury.
Compare this with white GaN LEDs, which are already 30 percent efficient and have a target efficiency of 60 percent. GaN LEDs are also incredibly long lasting: an LED can burn for 100,000 hours. In practical terms, this means it only needs replacing after 60 years of typical household use.
In the UK, lighting consumes over a fifth of all the electricity generated at power stations, and GaN LEDs have the potential to reduce this figure by at least 50 percent and possibly by 75 percent.
The Holy Grail for GaN is home and office lighting. Research directed at reducing manufacturing costs and improving the quality of light is bringing this goal closer.
Research at the Cambridge Centre for Gallium Nitride, directed by Colin Humphreys, the Director of Research in the Department of Materials Science and Metallurgy, stretches from fundamental materials studies through to applications and devices.
Green LEDs (Credit: Colin Humphreys)
The Centre has world-class GaN growth and characterisation facilities and has recently developed an innovative technique for growing GaN on large silicon wafers, instead of the more expensive sapphire wafers; this could deliver a tenfold reduction in LED manufacturing costs.
The Centre is also working on improving the quality of light by coating blue LEDs with phosphors to produce white light. This will be improved still further through the use of novel phosphors produced by Tony Cheetham in the Department of Materials Science and Metallurgy.
GaN LEDs have hit the market rapidly and are already widely used in flashlights and front bicycle lights, as backlighting for mobile phones and interior lighting in cars and aeroplanes, and even to light up landmarks such as the façade of Buckingham Palace and the length of the Severn Bridge. Looking ahead, the timescale for the widespread adoption of GaN LEDs in homes and offices is probably as short as 5 to 10 years.
Other applications also look promising. Research at the Centre is investigating the possibility of using GaN LEDs to mimic sunlight, which could have important benefits for sufferers of seasonal affective disorder (SAD).
And other studies are investigating how UV LEDs, created by adding aluminium to GaN, could be used for killing bacteria and stopping viruses from reproducing, either to purify water in the developing world or to ‘sweep’ hospital wards to eradicate superbugs.
The Cambridge Centre for Gallium Nitride is funded by the Engineering and Physical Sciences Research Council (EPSRC), the Technology Strategy Board (TSB), Aixtron Ltd, Sharp Electronics Europe, QinetiQ, Forge Europa, Philips, Imago Scientific Instruments and RFMD (UK) Ltd.
It is performed in collaboration with the University of Manchester and Sheffield Hallam University.
http://www.cam.ac.uk/research/news/lighting-for-the-21st-century
A revolution in lighting is under way. Thanks to advances in the technology, efficiency and cost of LEDs, these devices are ready to take over in the very near future from conventional forms of incandescent lighting.
The potential energy savings are huge: statistics from the US Department of Energy estimate that, by 2025, solid-state lighting such as LEDs could reduce the global amount of electricity used for lighting by 50 percent.
In the US alone, 258 million metric tons of carbon emission could be eliminated, alleviating the need for 133 new power stations, and result in cumulative financial savings of over a hundred billion dollars.
At the forefront of research underpinning this new lighting paradigm is a focus on the semiconductor gallium nitride (GaN) at the Cambridge Centre for Gallium Nitride in the Department of Materials Science and Metallurgy.
Why use GaN for LEDs?
LEDs based on GaN, which emits brilliant light when electricity is passed through it, are extremely energy efficient and long lasting. Traditional incandescent light bulbs are only 5 percent efficient at converting the electricity they consume into light, and, although low-energy light bulbs are 20 percent efficient, they contain hazardous mercury.
Compare this with white GaN LEDs, which are already 30 percent efficient and have a target efficiency of 60 percent. GaN LEDs are also incredibly long lasting: an LED can burn for 100,000 hours. In practical terms, this means it only needs replacing after 60 years of typical household use.
In the UK, lighting consumes over a fifth of all the electricity generated at power stations, and GaN LEDs have the potential to reduce this figure by at least 50 percent and possibly by 75 percent.
The Holy Grail for GaN is home and office lighting. Research directed at reducing manufacturing costs and improving the quality of light is bringing this goal closer.
Research at the Cambridge Centre for Gallium Nitride, directed by Colin Humphreys, the Director of Research in the Department of Materials Science and Metallurgy, stretches from fundamental materials studies through to applications and devices.
Green LEDs (Credit: Colin Humphreys)
The Centre has world-class GaN growth and characterisation facilities and has recently developed an innovative technique for growing GaN on large silicon wafers, instead of the more expensive sapphire wafers; this could deliver a tenfold reduction in LED manufacturing costs.
The Centre is also working on improving the quality of light by coating blue LEDs with phosphors to produce white light. This will be improved still further through the use of novel phosphors produced by Tony Cheetham in the Department of Materials Science and Metallurgy.
GaN LEDs have hit the market rapidly and are already widely used in flashlights and front bicycle lights, as backlighting for mobile phones and interior lighting in cars and aeroplanes, and even to light up landmarks such as the façade of Buckingham Palace and the length of the Severn Bridge. Looking ahead, the timescale for the widespread adoption of GaN LEDs in homes and offices is probably as short as 5 to 10 years.
Other applications also look promising. Research at the Centre is investigating the possibility of using GaN LEDs to mimic sunlight, which could have important benefits for sufferers of seasonal affective disorder (SAD).
And other studies are investigating how UV LEDs, created by adding aluminium to GaN, could be used for killing bacteria and stopping viruses from reproducing, either to purify water in the developing world or to ‘sweep’ hospital wards to eradicate superbugs.
The Cambridge Centre for Gallium Nitride is funded by the Engineering and Physical Sciences Research Council (EPSRC), the Technology Strategy Board (TSB), Aixtron Ltd, Sharp Electronics Europe, QinetiQ, Forge Europa, Philips, Imago Scientific Instruments and RFMD (UK) Ltd.
It is performed in collaboration with the University of Manchester and Sheffield Hallam University.
http://www.cam.ac.uk/research/news/lighting-for-the-21st-century