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Alison Ciesla, Martin Green and Zhengrong Shi Alison Ciesla, Martin Green and Zhengrong Shi

UNSW Sydney solar pioneers celebrate 50 years of world-leading research and innovation

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Louise Templeton
Louise Templeton,

The technology that’s lighting up the world, and its journey from the scrapheap to humanity’s great energy hope.

Name three iconic Aussie inventions. What comes to mind? Google Maps? The black box flight recorder? The Cochlear implant, perhaps?

What about solar cells, which are on more than 30% of Australian homes? The technology behind this clean, green energy was invented by Australians, too.

Economist Jeremy Rifkin wrote in his book,The Third Industrial Revolution,that solar is pivotal to the next phase of world economic development. He argued it will be a major driver as the globe shifts to a more sustainable economy.

The team who invented the solar cells at UNSW, led by Scientia Professor Martin Green, had no idea how world-changing their work would become.

Department head Prof. Lou Davies and Prof. Martin Green in UNSW's first solar research lab (1977). Photo: UNSW

Prof. Green set up Australia’s first solar research lab 50 years ago, in 1974.

He said: “The dream of a world powered by sustainable energy sources of course motivated me hugely, but that we were about to set out on a path that would one day result in a seismic shift in global energy generation and consumption was not a given.”

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Prof. Martin Green (centre) with Scientia lecturer Dr Alison Ciesla, whose late father Prof. Stuart Wenham played a pivotal role in UNSW's solar success, and UNSW alumnus Dr Zhengrong Shi, who started the first solar panel manufacturing company in China in 2001. Photo: Maja Baska

Humble beginnings

Prof. Green described how his first lab was set up in a meeting room off the professorial office of his departmental head, Lou Davies.

“Lou gave me some space and helped to rescue some technical equipment from the rubbish heap for my fledgling group.

“We had a crack team of young researchers, among them my first three PhD students, Bruce Godfrey, Andrew Blakers and Stuart Wenham, who were driven, inspired and passionate about the possibilities of pushing the technology to new levels,” he said.

Prof. Green and his colleagues developed their first working ‘TOPCon’ solar cell by 1981, becoming the first to demonstrate the viability of this technology. In 1983 they beat the rest of the world – including NASA and Stanford University, which were also racing to develop the technology – producing the most efficient silicon solar cell globally. This established UNSW’s reputation on the world stage, attracting international grants funding and the opportunity to accelerate their research.

The UNSW team that developed the first 20% efficient PERC solar cell (1985). Photo: UNSW

The birth of the modern solar cell

The team knew that if they were ever going to realise the dream of producing the cells commercially, they’d need to push the efficiency – the ratio of energy that falls on solar panels as sunlight to the electricity produced as a result – to the limit to cut manufacturing costs as much as possible.

Prof. Green devised a cell that was simpler to fabricate than the earlier models. He led the team that invented the Passivated Emitter and Rear Cell (PERC) in 1983, a project that changed the course of history.

PERC helped increase the conversion efficiency of standard solar cells by over 50% in relative terms from 16.5% in the early 1980s to 25% in the early 2000s.

“The team was reinforced by my first four Chinese-born PhD students in the late 1980s and early 1990s – Jianhua Zhao, Zhengrong Shi, Aihua Wang and Ximing Dai – who became Australian citizens. They, along with our equipment guru, Ted Szpitalak, played a crucial role not only in our cell development, but in the solar cost reductions of the last decade. This was done by founding and attracting US investment into three of the first companies manufacturing in China via Australian-Chinese joint ventures.”

The world's first Bachelor of Photovoltaic Engineering graduates (2004). Photo: UNSW

The world’s first solar undergraduate degree

It wasn’t just silicon solar cells that were first developed at UNSW. Building on their research strengths and thanks to their visionary leadership, the late Professor Stuart Wenham and Prof. Green established the world's first undergraduate teaching programme in photovoltaics (solar) and renewable energy engineering in 2000. It’s been 20 years since the first students graduated. The University’s 2000-plus solar alumni are among the most sought-after talent in the sector worldwide.

The Head of the School of Photovoltaic and Renewable Energy Engineering (SPREE), Professor Alistair Sproul, said he was incredibly proud of the significant role UNSW academics and graduates have had in the renewable energy transition.

“SPREE’s success in conceiving and developing world-leading technologysuch as PERC and TOPcon means UNSW technology is now at the heart of about 90% of all solar modules produced today,” he said.

“Prof. Green has consistently had an enormous impact over the past 50 years, always at the forefront of photovoltaic research as well as successfully transferring many technologies to industry.And his success has attracted incredibly talented and like-minded people to accelerate research in photovoltaics and sustainable energy even further.”

Head of the School of Photovoltaic & Renewable Energy Engineering, Prof. Alistair Sproul, speaking at the event to mark the 50 year anniversary of solar technology research at UNSW and 20 years since the first graduates in the field. Photo: Maja Baska

Celebrating 50 years of solar technology research and 20 years since the first graduates

Prof. Green joined some of SPREE’s former students – now in senior industry roles – on a panel at the weekend, at an event to mark the two milestone anniversaries – and to talk about what the future holds for solar energy.

ٰargued Australia has a phenomenal opportunity to become a major green energy exporter by harnessing the country’s renewable resources, along with our homegrown expertise.

believes Australia has the potential to lead in integrating renewables and operating large grids. He said it’s possible for the East Coast grid to be operating at 100% renewables within 10 years.

ٰis excited about producing super-cheap solar technology at large scale, and believes we have legitimate technology pathways to get there.

ٰsays we have the capacity to recycle old panels to create new ones, and that by 2045, all solar panels could be manufactured from old ones.

Prof. Green said photovoltaics is already the cheapest electricity in history, and he’s working on ways to make it even cheaper in the future.

A panel of accomplished SPREE alumni spoke about key challenges and hopes for the future of solar energy. From left: Oliver Hartley, Nicole Kuepper-Russell, Chris Davies, Rong Deng, Martin Green, Alison Ciesla (moderator). Photo: Maja Baska

Chasing the dream – new solar technology research

Fifty years on from when he started, Prof. Green is still in the trenchesof solar energy research, with no signs of slowing down.

He said: “PERC kickstarted the solar boom. But there is still enormous scope for improvement, such as through tandem cell stacks with the potential to drastically increase the energy output.

“Silicon cells are very good at converting red photons from sunlight, but not so efficient at converting blue ones, since they waste a lot of their energy. So we’re working on stacking cells on top of each other, which would work in tandem to convert different parts of the solar spectrum into electricity. We believe this innovation could boost commercial cell efficiency to over 40% in future,” Prof. Green said.

The future is green. Tell that one the next time you’re asked to name a legendary Aussie invention.