Scientists develop sunlight method to convert plastic waste into hydrogen

A team led by University of Adelaide PhD candidate Xiao Lu has published findings in Chem Catalysis on converting plastic waste into hydrogen, syngas, and industrial chemicals. The method treats plastics—produced at over 460 million tonnes annually worldwide—as a carbon- and hydrogen-rich resource rather than mere pollution. Sunlight activates photocatalysts to reform plastics into clean fuels, potentially aiding a circular economy and reducing reliance on fossil fuels. “Plastic is often seen as a major environmental problem, but it also represents a significant opportunity,” said Ms. Lu. “If we can efficiently convert waste plastics into clean fuels using sunlight, we can address pollution and energy challenges at the same time.” The process outperforms traditional water splitting for hydrogen by requiring less energy, as plastics oxidize more readily. Experiments have produced high hydrogen levels, acetic acid, and diesel-range hydrocarbons, with some systems operating continuously for over 100 hours. Senior author Professor Xiaoguang Duan from the School of Chemical Engineering highlighted challenges. “One major hurdle is the complexity of plastic waste itself,” he said. Different plastics and additives like dyes complicate conversion, necessitating better sorting and pretreatment. Photocatalysts must also improve in selectivity and durability to withstand harsh conditions without degrading. Additional obstacles include separating mixed gas and liquid products, which demands energy-intensive steps. The researchers advocate integrated solutions such as advanced catalyst designs, continuous-flow reactors, and hybrid solar systems. “This is an exciting and rapidly evolving field,” Ms. Lu added. “With continued innovation, we believe solar-powered plastic-to-fuel technologies could play a key role in building a sustainable, low-carbon future.”