Dr. Fernando Albarracin from the Technology Innovation Institute has presented a novel microwave applicator design for hyperthermia, potentially useful in cancer treatment. The design combines two flat dielectric graded-index (GRIN) lenses to localize electromagnetic energy within a specific spot in the tissue. This system offers a suitable alternative to conventional antenna-based applicators by considering the interface between free space and human tissue. Why it matters: This research introduces a new approach to hyperthermia treatment that could improve the precision and effectiveness of cancer therapy in the region.
KAUST Ph.D. student Muhammad Akram Karimi won the Three Minute Thesis competition at the IEEE MTT International Microwave Symposium in Boston. Karimi's presentation, titled "Making Materials Smart Using Microwaves," detailed his research on low-cost in situ microwave sensors. His work, in collaboration with Saudi Aramco, focuses on detecting water fraction in oil using sensors printed directly on pipes. Why it matters: This award recognizes innovative research at KAUST and highlights the potential of microwave sensor technology for applications in the oil and water industries within the region.
KAUST Ph.D. student Muhammad Akram Karimi is developing low-cost microwave sensors for industrial applications, particularly in the oil industry, under the supervision of Professor Atif Shamim. He is working on a field prototype for Saudi Aramco based on his novel design. Karimi and his professor plan to form a startup to provide microwave sensing solutions and are collaborating with a Norwegian company to commercialize their sensor. Why it matters: This highlights KAUST's focus on industry-relevant research and its potential for commercialization through startups, particularly in the important oil and gas sector.
KAUST researchers are exploring novel chemical reactors and separation processes using mathematical design, with a focus on time and shape variables to enhance transport, heat transfer, and mass transfer. By aligning design, modeling, and 3D printing, they create customized shapes with great complexity and less material. This approach allows for the creation of bespoke reactors and separation processes tailored to specific applications, improving efficiency and reducing energy consumption. Why it matters: This research demonstrates the potential of advanced manufacturing techniques to revolutionize industrial design in the Middle East's chemical and pharmaceutical sectors.
The Directed Energy Research Center (DERC) in the UAE has partnered with the University of Pisa to develop electronically controlled surfaces for dynamic broadband radio-absorption. This collaboration aims to test new materials and manufacturing processes for flexible radio-absorbing surfaces suited for harsh environments like the UAE. The project seeks to create smart-shields, active electromagnetic frequency selective surfaces, and electromagnetic energy harvesting surfaces. Why it matters: The partnership accelerates innovation in applied electromagnetics and could lead to advancements in telecommunications, energy, and electromagnetic protection in the region.
Prof. Agostino Monorchio has been appointed to the Board of Advisors of the Directed Energy Research Center (DERC). He will advise on flexible conformal metasurfaces for electromagnetic applications, bringing expertise from the University of Pisa and international research tenures. His research spans computational electromagnetics, metamaterials, antenna design, and biomedical microwave applications. Why it matters: The appointment strengthens DERC's advisory capabilities in directed energy research, potentially advancing technological innovation in the UAE.
A KAUST team led by Husam Alshareef has developed a microfabricated energy storage device with high energy and power density. The device uses nickel hydroxide as an active electrode material and achieves a volumetric capacitance density of 325 F/cm3. Fabricated using chemical bath deposition at room temperature, the device can power microelectronic devices. Why it matters: This research advances energy storage technology in the region, potentially impacting the development of microelectronics and portable power solutions.
DERC is partnering with EPFL in Switzerland on a four-year project using EMTR and ML to study electromagnetic disturbance localization in PCBs. Professor Farhad Rachidi (EPFL) and Dr. Nicolas Mora (DERC) will mentor a PhD student. The collaboration builds on prior relationships between DERC researchers and Prof. Rachidi's lab. Why it matters: The partnership strengthens DERC's methodological expertise and international recognition in electromagnetic studies, potentially leading to further collaborations.