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By  Asaesja Young 26 August 2024 6 min read

Key points

  • Silicon, in the form of quartz, is a fundamental ingredient for solar cells and other key technologies.
  • Australia has rich rock quartz deposits and world-class solar resources and photovoltaic generation potential.
  • Our new report, From minerals to materials, highlights the research and development needed to capitalise on critical minerals, including silicon.

With the global push towards renewable energy, the role of critical minerals has never been more heightened. Silicon, in the form of quartz, is a fundamental ingredient for solar cells and other key technologies. It's emerging as a linchpin in the quest for a sustainable future.

Yet, the journey from hard rock quartz to solar cell is complex, and Australia's potential to contribute to this journey is still unfolding.

From quartz to solar cell

Solar photovoltaic (PV) technology is set to dominate global energy generation by 2050. However, the current supply chain for solar cells is heavily concentrated in China, posing significant risks related to reliability of supply. 

Solar panel

The pathway from quartz to solar cell begins with the extraction of high-quality lump quartz from rock, which is primarily composed of silicon dioxide. The quartz doesn’t need to be of very high purity, but it does need to be physically strong enough to cope with the next step, without shattering to dust.

This quartz undergoes a reductive smelting process, where it is heated to extremely high temperatures. A carbon source, often coal or charcoal, reacts with the silicon dioxide, isolating silicon metal and producing carbon dioxide as a byproduct.

The resulting metallurgical-grade silicon has a purity level of about 99.0 per cent to 99.6 per cent. It then needs further chemical purification to create polysilicon with a purity level of 99.9999999 per cent or more.

This highly purified polysilicon is then melted and shaped into cylindrical ingots, which treated (doped) with boron or phosphorus to change their electrical photovoltaic properties.

These ingots are sliced into thin wafers, about 0.16 mm thick, which serve as the core components of solar cells. The wafers undergo further processing and are assembled into solar cells. These are then soldered together and placed onto a polymer back sheet, coated with specialised glass, and framed by aluminium racks to form complete solar panels or modules.

Australia's unique position to challenges

Australia, with its rich rock quartz deposits and world-class solar resources and solar PV generation potential, is uniquely positioned to develop a domestic silicon production industry. 

[Music plays and a split circle appears and photos of different CSIRO activities flash through in either side of the circle and then the circle morphs into the CSIRO logo]

[Image changes to show text “Silicon” on a white screen, and then the image changes to show an animation of a rotating world globe, and then the animation image changes to show a dump truck]

Narrator: Silicon is one of the most abundant elements on our planet, with the most common form being silica sand or SiO2. 

[Animation images move through to show a concrete mixer truck, the sun shining on a solar panel, three computer screens, and a car moving across the screen from the left to the right]

SiO2 is a vital starting material for concrete, solar panels, fibre optics, and even aluminium alloys used in your car.

[Animation image changes to show a glowing light bulb on the left linked to a wind turbine on the right]

We need a lot of pure silicon for the energy transition especially. 

[Animation image changes to show a solar PV on the left and on the right of the screen, and text appears between: 4 terawatt hours]

The world requires 4TW hours of solar PV by 2050, making the demand even greater.

[Animation images move through to show the sun shining on solar panels, a piece of quartz rock, a lump of elemental silicon, a lump of poly silicon, a solar cell, and then a group of solar panels]

Solar panels are made from a form of silica called high purity quartz, which is first reduced into elemental silicon, then upgraded to poly silicon, cells, and then into panels. 

[Animation image changes to show symbols of the process of producing solar panels joined across the bottom of the screen and CO2 clouds appear moving up from the process chain]
 
This lengthy process generally produces a lot of CO¬2, and with a fragile global supply chain Australia has the chance to make a big difference.

[Animation images move through to show a world map showing the USA, and then China, and then Australia highlighted on the map]

Currently the United States supplies a lot of the quartz, while China produces the vast majority of the world’s poly silicon and solar panels.

[Camera zooms in on Australia on the map, and then symbols of quartz appear over the map, and then the symbols of quartz are replaced with symbols of solar panels]

With Australia’s access to high purity quartz, and the growing demand for solar PV, we have the potential to become an industry leader in producing clean, renewable electricity.

[Animation image changes to show a dump truck with a load of quartz in the back]

But it will take work to establish our own supply chains and ensure carbon neutrality.

[Animation image changes to show a process flow chart joining symbols of a sun shining on a solar panel, quartz, elemental silicon, poly silicon, green hydrogen, a solar cell, and a group of solar panels]

Considering new process techniques, like the use of green hydrogen to replace carbon reductants is essential. 

[Animation image changes to show the sun shining on a landscape, and then the camera zooms out to show a map Australia highlighted in a world map]

This is our chance to become a leader in green silicon and poly silicon production and in creating new industries.

[Music plays and the image changes to show text on a white screen: CSIRO, Australia’s National Science Agency]

Will you join us?
 

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This move could enhance national energy security, reduce carbon emissions, and create economic opportunities.

Australia also has a competitive advantage because of its potential for low-cost, low-emissions electricity from solar and wind, existing bulk-commodity export infrastructure, and large deposits of high-quality quartz.

However, the challenge for Australia is in establishing polysilicon, ingot and wafer manufacturing – an area where Australia has limited experience. But it is possible to overcome this through partnerships with international technology leaders.

If successful, this would address the most concentrated part of the value chain and create opportunities for both domestic and export markets.

Currently there is only one silicon manufacturing facility in Australia – Simcoa in Western Australia, which is Japanese-owned. It produces 52,000 tonnes of metallurgical silicon each year, and exports approximately 85 per cent of its total production.

Senior Consultant at global mineral economics firm CRU International, David Royle, said China maintained a global market share of around 94 per cent of polysilicon for use in solar PV cells.

"It would be highly costly for Australia to enter this established market and the prices for polysilicon for example have been historically highly volatile, with a more recent dynamic emerging showing division of price between China and ex-China material," David said.

"While establishing this industry would be challenging, if we do it right, it could also be really successful and create a sustainable and important domestic industry for Australia. Key to Australia pulling this off is access to stable, cheap energy as well as incentives like the tax credits provided in the Future Made in Australia Act."

2024 polysilicon production capacity by location, per cent of global. Credit Exawatt, CRU

A recent dynamic is emerging between prices for China and Ex-China materials. Credit Exawatt, CRU

The Australian Critical Minerals Research and Development Hub

The Australian Critical Minerals Research and Develop Hub, which partners us with Geoscience Australia and the Australian Nuclear Science and Technology Organisation (ANSTO), is pioneering innovative exploration techniques and fostering industry partnerships to advance the discovery and development of critical minerals in Australia. This includes high-quality quartz deposits.

Critical Mineral R&D Hub Lead for ANSTO, Dr Chris Griffith, said as part of the Hub’s work, ANSTO was leading the investigation of refining technologies for quartz, developing advanced methods that enhance the purity and quality of this critical mineral.

"High temperature chlorination involves exposing an already ‘high purity’ silica material to chlorine gas at temperatures higher than 1000 degrees Celsius," Chris said.

"These conditions result in the formation of hydrogen chloride or chloride salts of the key impurity elements, which can be subsequently removed by chlorination or dissolution through leaching.

"However there aren’t many facilities capable of conducting such high temperature chlorination and even fewer dedicated to high purity quartz, so one of our key objectives it to provide such a facility for validation purposes for Australian industry."

A key feature of ANSTO’s work on the purification of quartz is the production of materials that could be used to form crucibles for high purity silicon and polysilicon production. Although extremely high purity silicon gets the limelight, very high purity quartz is essential to manufacture crucibles and containment vessels that do not contaminate the high purity silicon.

Our new report, From minerals to materials, funded by the Critical Minerals Office in the Department of Industry, Science and Resources, highlights the research and development needed to fully capitalise on specific critical mineral markets, including silicon. It will inform the Australian Critical Minerals Research and Development Hub.

Lead author of the report, Beni Delaval, said focused research and development (R&D) could help Australia capitalise on its market opportunities by creating new and more efficient pathways that were less costly and more environmentally sustainable.

"When it comes to silicon metal, one of the opportunities highlighted in the report is a less carbon intensive production process, through the use of biocarbon resources," Beni said.

"There are also other refining practices which have a smaller carbon footprint, which warrant further investigation.

"While there are plenty of opportunities for Australia, getting this industry operational will require strong international collaboration, along with national collaboration between government, industry and the research sector."

The broader opportunity and strategic coordination

David said the silicon metal opportunity for Australia extended beyond solar cells.

"Silicon is also seeing increased use in battery anode chemistries, where blended up to 20 per cent with graphite, can yield significant energy density improvements and cost reduction," David said.

"CRU estimates that nearly 50 per cent of battery anodes in light-duty battery electric vehicles will contain silicon," David said.

Australia has a golden opportunity to become a global leader in the silicon supply chain, driving the transition to renewable energy and securing economic and environmental benefits. By acting swiftly and strategically, and through coordinated R&D efforts and international and domestic collaboration, Australia can turn its rich mineral endowment into a powerhouse of clean energy, showcasing the true potential of its critical minerals quiet achievers.

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