High-efficiency solar cells
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Using arrays of long, thin silicon wires embedded in a polymer substrate, a team of scientists from the California Institute of Technology (Caltech) has created a new type of flexible solar cell that efficiently converts photons into electrons.
‘These solar cells have, for the first time, surpassed the conventional light-trapping limit for absorbing materials,’ said Harry Atwater, Howard Hughes professor of applied physics and materials science at Caltech.
The light-trapping limit of a material refers to how much sunlight it is able to absorb.
The silicon-wire arrays absorb up to 96 per cent of incident sunlight at a single wavelength and 85 per cent of total collectible sunlight.
The silicon-wire arrays are able to convert between 90 and 100 per cent of the photons they absorb into electrons.
The key to the success of the solar cells is their silicon wires, each of which, said Atwater, are independent highly efficient and high-quality solar cells.
When brought together in an array, however, they’re even more effective, because they interact to increase the cell’s ability to absorb light.
Light comes into each wire and a portion is absorbed and another portion scatters.
The collective scattering interactions between the wires make the array very absorbing.
This effect occurs despite the sparseness of the wires in the array - they cover only between two to 10 per cent of the cell’s surface area.
The new solar cells also use only a fraction of the expensive semiconductor materials required by conventional solar cells.
Just two per cent of the cell is silicon, while 98 per cent is polymer.
Since the silicon material is an expensive component of a conventional solar cell, a cell that requires just two per cent of the amount of semiconductor material will be much cheaper to produce.
The composite nature of these solar cells, Atwater added, means that they are also flexible. ‘Because flexible thin films can be manufactured in a roll-to-roll process, it is an inherently lower-cost process than one that involves brittle wafers like those used to make conventional solar cells,’ he said.
The next steps, Atwater said, are to increase the operating voltage and the overall size of the solar cell. ‘The structures we’ve made are square centimetres in size,’ he explained. ‘We’re now scaling up to make cells that will be hundreds of square centimetres - the size of a normal cell.’
Atwater says that the team is already ’on its way’ to showing that large-area cells work just as well as these smaller versions.
![Schematic diagram of the light-trapping elements used to optimise absorption within a polymer-embedded silicon wire array. [Credit: Caltech/Michael Kelzenberg]](/Pictures/web/s/u/c/body.jpg)
Schematic diagram of the light-trapping elements used to optimise absorption within a polymer-embedded silicon wire array [Credit: Caltech/Michael Kelzenberg]
![Schematic diagram of the light-trapping elements used to optimise absorption within a polymer-embedded silicon wire array. [Credit: Caltech/Michael Kelzenberg]](/pictures/58xAny/5/4/0/2027540_body.jpg)
Readers' comments (6)
Anonymous | 19 Feb 2010 5:04 pm
Will these be more eficient than conventional PV panels and if so how much ?
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John | 1 Mar 2010 2:01 pm
Cant wait to see this discovery become commercial and available worldwide.
As you know solar panels at present are only at best and unfortunately15% efficient .
This technology could pave the way for highly efficient solar homes with only a few panels not 10 to 20 as we presently install.
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Brendan | 2 Mar 2010 1:42 am
95% efficient at a single wavelength is expected to mean what, exactly? How much more energy (over a year for 1 sq metre say) can we expect here?
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Prof.(Dr.) Ram Kishore | 30 Aug 2010 8:26 pm
I highly appreciate the idea. In fact I have grown silicon nanowires in amorphous silicon at low temperatures using aluminum induced crystallization while working at University of Arkansas, Faytteville, USA with Prof. Naseem. We are yet to transform these silicon nanowires in amorphous silicon for absorbing more light and yielding higher efficeincy solar cells. In fact Prof. Martin Green has given a scheme of getting solar cell of more than 75% efficeincy initiallly at PVSEC 2004 at Shanghai and yest the realization is possible. I congratulate Atwater for this great idea.
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Anonymous | 23 Nov 2010 5:50 pm
When will we be able to purchase these? At what price?
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Anonymous | 18 Nov 2011 11:27 am
I am assuming that these will not only be cheaper to produce but lighter and more flexable? I hope this study can replicate the 96% absorption rate when produced on a larger scale.
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