A new solar cell configuration developed by engineers at the University of New South Wales has pushed sunlight-to-electricity conversion efficiency to 34.5% – establishing a new world record for unfocused sunlight and nudging closer to the theoretical limits for such a device.

The record was set by Dr Mark Keevers and Professor Martin Green, Senior Research Fellow and Director, respectively, of the University of New South Wales’s Australian Centre for Advanced Photovoltaics, using a 28 cm² four-junction mini-module – embedded in a prism – that extracts the maximum energy from sunlight. It does this by splitting the incoming rays into four bands, using a hybrid four-junction receiver to squeeze even more electricity from each beam of sunlight.

The new result, confirmed by the US National Renewable Energy Laboratory, is almost 44% better than the previous record – made by Alta Devices of the US, which reached 24% efficiency, but over a larger surface area of 800 cm².

‘This encouraging result shows that there are still advances to come in photovoltaics research to make solar cells even more efficient,’ said Keevers. ‘Extracting more energy from every beam of sunlight is critical to reducing the cost of electricity generated by solar cells as it lowers the investment needed, and delivering payback faster.’

The result was obtained by the same team that set a world record in 2014, achieving an electricity conversion rate of over 40% by using mirrors to concentrate the light – a technique known as CPV (concentrator photovoltaics) – and then similarly splitting out various wavelengths. The new result, however, was achieved with normal sunlight with no concentrators.

 ‘What’s remarkable is that this level of efficiency had not been expected for many years,’ said Green, a pioneer who has led the field for much of his 40 years at the University of New South Wales. ‘A recent study by Germany’s Agora Energiewende think tank set an aggressive target of 35% efficiency by 2050 for a module that uses unconcentrated sunlight, such as the standard ones on family homes.’

Australia’s research in photovoltaics has already generated flow-on benefits of more than $8 billion to the country, Green said. Gains in efficiency alone, made possible by PERC cells, are forecast to save $750 million in domestic electricity generation in the next decade. PERC cells were invented at the University of New South Wales and are now becoming the commercial standard globally.

The record-setting mini-module combines a silicon cell on one face of a glass prism, with a triple-junction solar cell on the other.

The triple-junction cell targets discrete bands of the incoming sunlight, using a combination of three layers: indium–gallium–phosphide, indium–gallium–arsenide, and germanium. As sunlight passes through each layer, energy is extracted by each junction at its most efficient wavelength, while the unused part of the light passes through to the next layer, and so on.

Some of the infrared band of incoming sunlight, unused by the triple-junction cell, is filtered out and bounced onto the silicon cell, thereby extracting just about all of the energy from each beam of sunlight hitting the mini-module.

The 34.5% result with the 28 cm² mini-module is already a world record, but scaling it up to a larger 800 cm² – thereby leaping beyond Alta Devices’ 24% – is well within reach. ‘There’ll be some marginal loss from interconnection in the scale-up, but we are so far ahead that it’s entirely feasible,’ Keevers said. The theoretical limit for such a four-junction device is thought to be 53%, which puts this result two-thirds of the way there.

Multi-junction solar cells of this type are unlikely to find their way onto the rooftops of homes and offices soon, as they require more effort to manufacture and therefore cost more than standard crystalline silicon cells with a single junction. But the team is working on new techniques to reduce the manufacturing complexity, and create cheaper multi-junction cells.

However, the spectrum-splitting approach is perfect for solar towers, like those being developed by Australia’s RayGen Resources, which use mirrors to concentrate sunlight, which is then converted directly into electricity.

The research is supported by a $1.4 million grant from the Australian Renewable Energy Agency (ARENA). The University of New South Wales team is working with another ARENA-supported company, RayGen, to explore how the advanced receiver could be rolled out at concentrated solar PV power plants. Other research partners are Trina Solar, a PV module manufacturer and the US National Renewable Energy Laboratory.