KAUST researchers have developed a system to convert captured carbon dioxide into industrial-grade ethylene using a high-pressure electrolyzer. The system operates under realistic industrial conditions and uses captured, high-pressure CO₂. It reduces the energy cost of producing ethylene by 0.8 gigajoules per metric ton compared to existing electrolysis systems. Why it matters: This innovation presents a direct path for transforming greenhouse gas emissions into valuable chemical products, aligning with Saudi Arabia's circular economy goals.
KAUST postdoctoral fellow Adrian Galilea is working at the Catalysis Center on sustainable production of chemicals from carbon dioxide. The research involves synthesizing a catalyst for the hydrogenation of CO2 to olefins and aromatics. The new material reportedly converts CO2 to these chemicals with high selectivity and productivity. Why it matters: Developing sustainable chemical production methods could reduce reliance on fossil fuels and address climate change.
KAUST Ph.D. student Reem Alghamdi is working at the KAUST Catalysis Center to improve the quality of industrially used polyethylene. Her research focuses on synthesizing a nanocomposite of polyethylene and nanomaterials to reinforce industrially made polymers, improving their mechanical characteristics. The resulting hybrid organic-inorganic product minimizes manufacturing defects, enhancing hardness. Why it matters: This research has the potential to significantly improve the durability and performance of polymer products across various sectors, from automotive to construction, impacting numerous industries in the region and beyond.
KAUST Professor Nikos Hadjichristidis received the ACS Award in Polymer Chemistry at the 249th American Chemical Society National Meeting & Exposition. The award, sponsored by ExxonMobil Chemical Company, is the highest honor in polymer science. Hadjichristidis's research focuses on synthesizing polymeric materials with complex macromolecular architectures and collaborating with SABIC on polyethylene-based polymeric materials. Why it matters: This award recognizes KAUST's contributions to advanced materials research and highlights the importance of polymer science for industrial applications within Saudi Arabia, particularly in collaboration with companies like SABIC and ExxonMobil.
KAUST researchers collaborated to identify molecular pathways for plant biofortification of vitamin A. A KAUST group demonstrated high pressure conversion of carbon dioxide into useful products. Another team designed a biosensor using metal oxide transistors to detect glucose in saliva. Why it matters: These projects highlight KAUST's contributions to biotechnology, environmental sustainability, and healthcare through advanced materials and molecular techniques.
KAUST researchers have determined the atomic 3D structure of a key protein involved in plant stress signaling using X-ray crystallography at the SOLEIL synchrotron in France. Postdoctoral fellow Umar Farook Shahul Hameed optimized a tiny crystal of the plant enzyme for over six months. The team used the EIGER 9M detector to capture the weak diffraction pattern from the crystal. Why it matters: Understanding the interactions between proteins that communicate plant stress could lead to engineering more stress-tolerant crops, enhancing food security.
KAUST researchers have developed a surface treatment for jute storage bags to prevent moisture-induced damage to stored grains. The treatment involves roughening the jute surface with an alkali and applying a thin layer of paraffin wax. Experiments showed that seed moisture content reduced by up to 7.5 percent in wax-coated bags, and seed germination efficacy after storage was up to 35 percent higher. Why it matters: This simple, scalable technique could significantly reduce grain losses in developing countries and provide an environmentally friendly alternative for grain storage.
KAUST and Aramco have developed a one-step crude-to-chemicals (C2C) technology that converts crude oil to light olefins in a single-reactor system. The technology, published in Nature Catalysis, aims to maximize the production of materials used in daily life over fuels. Aramco is pursuing growth opportunities in petrochemicals using the C2C method. Why it matters: The C2C breakthrough aligns with Saudi Vision 2030 and could reduce the carbon footprint associated with oil use, creating jobs and supporting a thriving economy.