Solar cell inspection tool evolution set to slash manufacturing costs by billions
AI Analysis
Summary
Researchers at the University of New South Wales in Sydney are working with the institution’s spinoff company BT Imaging to accelerate the commercialization of solar cell defect detection technology, thanks to a AUD 2.1 billion ($1.4 billion) project.
<p class="p1"><span class="s1">Researchers at the University of New South Wales in Sydney are working with the institution’s spinoff company BT Imaging to accelerate the commercialization of solar cell defect detection technology, thanks to a AUD 2.1 billion ($1.4 billion) project.</span></p><p><strong>From <a href="https://www.pv-magazine-australia.com/2025/11/05/solar-cell-inspection-tool-evolution-set-to-slash-manufacturing-costs-by-billions/" rel="noopener" target="_blank">pv magazine Australia</a></strong></p>
<nav>A breakthrough contactless inspection system developed at the University of New South Wales (UNSW) Sydney could soon become the new global standard in solar cell testing – cutting waste, doubling production speed and saving the photovoltaic industry an estimated AUD 2.1 billion a year. The ACDC (Artificial Intelligence, Characterisation, Defects and Contacts) Research Group at UNSW is partnering with the institution’s spinout company BT Imaging to accelerate the technology’s development, which incorporates advanced imaging and machine learning to produce detailed maps of key electrical parameters and defects in solar cells.Project lead Professor Ziv Hameiri said his team’s invention addressed urgent shortcomings in the quality control testing used by solar cell manufacturers.</nav>
<nav>“While solar cells have advanced dramatically in recent years, with more sophisticated structures and outstanding performance, the main quality inspection tool has remained largely unchanged for over a decade,” Hameiri said. “The incumbent ‘current voltage’ testers must physically touch the fragile surface of cells, which often leads to damage. The method also struggles with current cell components such as multi-busbars, zero-busbars, and back contacts, as well as <a href="https://www.pv-magazine.com/2025/06/25/australian-cell-manufacturer-launches-perovskite-module-series/">next-generation technologies like perovskite</a> and tandem solar cells.”Hameiri added that additionally, traditional testing methods can only be used in the late stages of cell production (post-metallisation), which means early-stage defects are missed and production is significantly slowed.</nav>
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<figure class="wp-caption alignnone" id="attachment_114532"><img alt="" class="size-medium wp-image-114532" height="389" src="https://www.pv-magazine-australia.com/wp-content/uploads/sites/9/2025/11/Screenshot-346-600x389.png" width="600" /><figcaption class="wp-caption-text"><i>Image: University of New South Wales Sydney</i></figcaption></figure>
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<p>Hameiri said the current testers were no longer suitable for measuring modern solar cells and faced even greater limitations with emerging technologies.</p>
<p>His team’s new system works by shining light onto a solar cell and analysing the faint glow it emits. This glow, or ‘luminescence’, reveals key electrical properties such as voltage, series resistance, and efficiency. Using advanced imaging and machine learning, test data can be converted into detailed maps of defects, performance and predicted lifespan.</p>
<p>“Through our collaboration with BT Imaging, we aim to reshape the industry by introducing contactless measurements that overcome the limitations of standard current-voltage testers, while offering lower cost, higher throughput and importantly, new insights that will make solar cells even more efficient and reliable,” Hameiri said.</p>
<p>The contactless system offers critical advantages over current testing methods: cells remaining intact during testing and defects can be detected earlier in production.</p>
<p>The technology works with both current <a href="https://www.pv-magazine-australia.com/2025/08/12/energus-to-run-feasibility-study-for-solar-grade-polysilicon-production-facility/" rel="noopener" target="_blank">silicon cells</a> and emerging perovskite and tandem solar cells, making it a versatile solution for bringing next-generation solar technologies into mass production.</p>
<p>BT Imaging Managing Director Dr Shubham Duttagupta said that as a UNSW spinoff, the company is built on the strength of academic research, and partnerships like this allowed his team to keep pushing innovation into the marketplace.</p>
<p>“By combining UNSW’s cutting-edge innovation with our commercialization expertise, we’re turning laboratory breakthroughs into practical, factory-ready products for both silicon and next-generation solar cells. We are creating inspection systems for manufacturers all around the world that are faster, more reliable, more accurate and future-proofed than ever before,” Duttagupta said.</p>
<p>The researchers are taking the solar cell inspection technology to market, thanks to a AUD 400,000 grant from the <a href="https://trace.org.au/" rel="noopener" target="_blank">Trailblazer Recycling & Clean Energy (TRaCE)</a> Lab to Market Fund and a $1 million contribution by <a href="https://www.btimaging.com/" rel="noopener" target="_blank">BT Imaging</a>.</p>
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