KAUST researchers Yichen Cai and Jie Shen, led by Dr. Vincent Tung, are developing electronic skin (e-skin) using 2D materials like MXenes. Their research, published in Science Advances, focuses on mimicking human skin functions like sensing and adapting to stimuli. The team leverages the unique properties of 2D materials to create flexible and efficient electronic systems for next-generation electronics. Why it matters: This work advances materials science in the region, potentially enabling breakthroughs in flexible electronics, healthcare monitoring, and robotics.
KAUST faculty received multiple gold and silver medals at the Geneva International Exhibition of Inventions 2025. Professor Dana Alsulaiman won the IFIA Best Invention Award for "Bio-MXenes," a portable biosensor for detecting microRNA cancer biomarkers from liquid biopsies. Other awarded projects included super-resolution imaging of ferromagnetic tubulars and rapid Zika virus detection. Why it matters: The awards highlight KAUST's role as a hub for groundbreaking research, especially in medical diagnostics and AI-enhanced imaging.
Sahika Inal, an assistant professor of bioscience at KAUST, focuses on organic electronic materials for clinical health monitoring. Her research involves finding functional polymers and designing electronic platforms that connect biological systems with electronics. Inal notes that KAUST's facilities and collaborative environment in BESE have been crucial for her research and team growth since 2016. Why it matters: This highlights KAUST's role in fostering interdisciplinary research and attracting talented scientists in the emerging field of bioelectronics.
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 and Chinese companies Shandong Lianxin Environmental Protection Technology and Hangzhou Hecai Technology will manufacture green plastics based on KAUST technology. The plastics, high molar mass aliphatic polycarbonates, are for biomedical products and food packaging due to their biodegradability and biocompatibility. KAUST's method creates these polycarbonates using CO2 and sustainable raw materials without toxic metals, with production scaling over two years. Why it matters: This partnership highlights KAUST's role in developing sustainable materials and bringing them to market, with potential impact on reducing reliance on traditional plastics in sensitive applications.
KAUST researchers reported the full genome sequencing of einkorn wheat in Nature. A new 'cooling score' metric was created to study heat's impact on solar cell performance. KAUST is also optimizing MXenes for lithium batteries and using biomimetic mineralization for smart agriculture. Why it matters: This research demonstrates KAUST's contributions to diverse fields, including genomics, sustainable energy, and smart agriculture, advancing technological innovation in Saudi Arabia.
KAUST researchers demonstrated a new flash memory device design using gallium oxide, which can withstand harsh environments. In collaboration with the University of Michigan, KAUST researchers explained a key molecular event for the activation of an enzyme associated with cancer. The Summer 2023 issue of KAUST Discovery is now available. Why it matters: These research achievements highlight KAUST's contributions to advanced materials science and biomedical research, with potential applications in space technology and cancer treatment.
KAUST Associate Professor Peiying Hong has developed a wastewater treatment method using anaerobic membrane bioreactor (AnMBR) technology, which converts organic carbon into methane. In partnership with MODON, a pilot program is operational in Jeddah, treating 23,000 liters of wastewater daily using UV light and hydrogen peroxide for disinfection. This system produces clean water suitable for agriculture and biomass for fertilizer, with a smaller footprint and lower energy consumption than traditional aerobic methods. Why it matters: The AnMBR technology aligns with Saudi Vision 2030's water reuse objectives, reducing reliance on energy-intensive desalination and offering a sustainable solution for water-stressed regions.