Korean scientists achieve 21% efficiency in polycrystalline solar cell for underwater environments

<p class="p1"><span class="s1">The cell was fabricated with a 2.3 nm-thin layer of gallium oxide, a silver busbar aimed at improving charge collection and silicon nitride anti-reflection coating. It was encapsulated within a watertight 3D-printed box to ensure impermeability.</span></p><p>Scientists from the Multidisciplinary Core Institute for Future Energies (MCIFE) in South Korea have fabricated a polycrystalline solar cell using a <span class="list-content">semiconductor–water interface</span> that reportedly <span class="list-content">improves light absorption, while reducing surface reflection and offering protection from environmental damage in underwater environments.</span></p>
<p>The cell was fabricated with a 2.3 nm-thin layer of gallium oxide (Ga₂O₃), which is a material with a large bandgap, high transparency, chemical robustness, and remarkable surface passivation properties. &#8220;When applied as an ultrathin layer, Ga₂O₃ can simultaneously serve as a passivation layer, protective barrier, and anti-reflective coating, thereby offering a pathway to enhance silicon solar cells beyond conventional designs,&#8221; the researchers explained.</p>
<p>&#8220;In addition to its optical advantages, Ga₂O₃ functions as a strong protective layer, especially in water-based environments. It helps to reduce degradation from chemical reactions, thereby improving the long-term stability, resistance to oxidation and resilience of the solar cells,&#8221; they added.</p>
<p>The 12 mm × 12 mm device also relies on a silver (Ag) busbar aimed at improving charge collection and silicon nitride (SiNx) anti-reflection coating. It was encapsulated within a watertight 3D-printed box to ensure impermeability.</p>
<figure class="wp-caption aligncenter" id="attachment_317294" style="width: 600px;"><img alt="" class="size-medium wp-image-317294" height="391" src="https://www.pv-magazine.com/wp-content/uploads/2025/09/1-s2.0-S0264127525011748-gr5-600x391.jpg" tabindex="0" width="600" /><figcaption class="wp-caption-text">A 3d printed enclosure box for water devices where ten devices are connected in series <p><i>Image: Multidisciplinary Core Institute for Future Energies (MCIFE), Materials & Design, CC BY 4.0</i></p>
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<p>The performance of the cell was measured and compared to that of a bare polycrystalline cell, a bare polycrystalline device for underwater environments, a gallium oxide deposited polycrystalline cell, and a gallium oxide deposited underwater polycrystalline cell.</p>
<p>All devices were tested by pulsed white light illumination under four different conditions: without Ga₂O₃ in air (W/O-Air); with Ga₂O₃ in air (W/G-Air); without Ga₂O₃ in water (W/O-Water); and with Ga₂O₃ in water (W/G-Water).</p>
<p>The measurements showed that the gallium oxide-deposited underwater polycrystalline cell is able to achieve the highest efficiency among all devices, with a percentage value of 21.56%, followed by the bare polycrystalline cell for underwater conditions with 19.36%, the gallium oxide-deposited polycrystalline cell with 19.04%, and the bare polycrystalline cell with just 17.87%.</p>
<p>&#8220;The results indicate that the presence of Ga₂O₃ significantly enhances the photocurrent in both air and water environments,&#8221; the academics emphasized. &#8220;Notably, the highest photocurrent is observed in the W/G-Water condition, suggesting that the combined effect of Ga₂O₃ and water improves charge transport efficiency.&#8221;</p>
<p>The &#8220;hybrid&#8221; solar cell was presented in the paper &#8220;<span class="title-text"><a href="https://www.sciencedirect.com/science/article/pii/S0264127525011748#f0005" rel="noopener" target="_blank">Aqua-powered hybrid solar cell using amorphous conformal Ga₂O₃ thin-film</a>,&#8221; published in <em>Materials & Design</em>.</span></p>
<p>The <a href="https://www.pv-magazine.com/2020/02/25/how-do-solar-cells-work-underwater/" rel="noopener" target="_blank">performance of underwater solar cells</a> was investigated in 2020 by scientists from the Birla Institute of Technology and Science and the Indian Institute of Technology Kanpur and Defence Materials. According to their findings, submerged cells benefit from lower temperatures and an ideal environment for cleaning. “Although there are challenges and limitations, the results obtained show that there is an enormous potential for solar PV technology in underwater monitoring sensors or devices, and various other commercial and defense applications with modern-day power electronics,” the researchers stated at the time.</p>
<p>In 2022, researchers in China used commercially available solar cells to create an <a href="https://www.pv-magazine.com/2022/02/17/photovoltaics-for-underwater-wireless-communication/" rel="noopener" target="_blank">underwater-optimized lens-free system</a> for high-speed optical detection and found that the PV devices enabled a much larger detection area than commonly used photodiodes.</p>
<p>In June of this year, researchers in Italy tested how <a href="https://www.pv-magazine.com/2025/07/02/perovskite-solar-cell-testing-in-underwater-environments-shows-surprising-efficiency-results/">perovskite solar cells could perform underwater</a> and found that, at very shallow depths, they may even achieve higher power conversion efficiencies compared to reference devices operating under out-of-water conditions.</p>
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