KAUST researchers developed a crystallization process for organic molecules with potential applications in electronics, pharmaceuticals, and food. They produced "strained organic semiconductors," which can lead to high-performance, low-cost, flexible, and transparent electronic devices. The team combined X-ray beams with high-speed cameras to record the crystallization process, revealing that quick evaporation and nanoscale thinness play a role in producing ideal crystal lattices. Why it matters: This new method offers unprecedented control over crystal formation, potentially revolutionizing the production of plastic electronics and impacting other industries relying on specific crystal structures.
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 are exploring thin-film device technologies using materials like printable organics and metal oxides for a greener Internet of Things (IoT). They propose wirelessly powered sensor nodes using energy harvesters to reduce reliance on batteries, which are costly and environmentally harmful. Large-area electronics, printed on flexible substrates, offer a more eco-friendly alternative to silicon-based technologies due to solution-based processing and lower production temperatures. Why it matters: This research contributes to a more sustainable and environmentally friendly IoT ecosystem, aligning with global efforts to reduce electronic waste and energy consumption.
Professor Jean-Luc Bredas, Director of KAUST’s Solar Center (SPERC), has been elected to the European Academy of Sciences (EURASC). Bredas is recognized for his theoretical research into organic materials for semiconductor devices like LEDs, transistors, and solar cells. His KAUST group focuses on understanding the electronic and optical properties of these materials. Why it matters: This recognition highlights KAUST's growing prominence in advanced materials research and its contributions to global scientific advancements in electronics and photonics.
KAUST researchers led by Dr. Muhammad Hussain have developed a flexible, transparent silicon-on-polymer based FinFET inspired by the folded architecture of the human brain's cortex. The team created a 3D FinFET on a flexible platform without compromising integration density or performance. They aim to demonstrate a fully flexible silicon-based computer by the end of the year. Why it matters: This research could lead to the development of ultra-mobile, foldable computers and integrated circuits, advancing the field of flexible electronics in the region.
KAUST and SABIC are collaborating on research in flexible electronics. The collaboration involves researchers from KAUST and SABIC's New Materials Solutions Group working together in KAUST labs. The research aims to develop innovations in new materials. Why it matters: This partnership highlights the increasing focus on materials science and advanced manufacturing within Saudi Arabia's research and development landscape.
Professor Iain McCulloch from KAUST has won the Royal Society of Chemistry's Interdisciplinary Prize. McCulloch was recognized for his work in designing and applying functional materials in optics, electronics, and energy. His research focuses on creating new organic materials for flexible solar cells and other applications. Why it matters: This award highlights KAUST's increasing role as a hub for innovative materials science research with global impact.
KAUST researchers collaborated with TSMC to review the potential of 2D materials in overcoming silicon limitations for microchips. They find that while 2D materials show promise, performance degrades when using scalable fabrication techniques like chemical vapor deposition. 2D materials have been integrated into some commercial products like sensors, but high-integration-density circuits are still a challenge. Why it matters: This research highlights the ongoing efforts and remaining hurdles in utilizing novel materials to advance semiconductor technology in line with industry roadmaps.