Photovoltaic researchers at UNSW demonstrate best-ever results for emerging solar cell material antimony chalcogenide.UNSW engineers have made a major ...

Perovskite solar cells, often called PeSCs, are changing the way energy is captured—especially indoors. Unlike the rigid and heavy silicon panels fixed to rooftops, these thin and flexible materials ...

Osaka Metropolitan University scientists have created a molecule that naturally forms p/n junctions, structures that are ...

A research team in Italy has tested the performance of semitransparent wide-bandgap perovskite solar cells in underwater (UW) environments and has found that, at a 0.5–1 cm depth, the devices achieve ...

Solar power is already one of the fastest growing sources of electricity on the planet, yet scientists say it is still only ...

An international research group has published breakthrough findings demonstrating how the ionic compound caesium bromide (CsBr) can significantly improve the efficiency of crystalline silicon (c-Si) ...

Single-crystalline TiO2 nanorods excel at harvesting light and conducting charge, making them ideal for solar cells, photocatalysts, and sensors. However, traditional fabrication methods link rod ...

What if the future of solar energy wasn’t just brighter but fundamentally redefined? Imagine a world where solar panels are not only more efficient but also cheaper, more durable, and adaptable to ...

A new study highlights a semi-transparent, color-tunable solar cell designed to work in places traditional panels can't, like ...

Researchers have developed a perovskite-organic tandem solar cell that achieves 26.4 percent efficiency. Unlike rigid silicon modules, the lightweight design can generate power on curved or flexible ...