KAUST's Workshop Core Lab has upgraded its scientific glassblowing workshop with advanced equipment like precision lathes and coating machines. The facility produces bespoke scientific glass equipment for KAUST researchers using borosilicate and quartz glass. Senior glassblowers Ernest Neil Davison and Emilio Harina create intricate designs from prototype sketches. Why it matters: This enhances KAUST's research capabilities by providing high-quality, specialized glassware that Davison claims rivals that of other top universities globally.
KAUST's Workshops Core Lab launched the first scientific glassblowing apprenticeship program in Saudi Arabia. The program trains Saudi apprentices in the specialized skills of scientific glassblowing, essential for creating and repairing glassware used in research. Apprentices Faisal Nour and Mohammed Al-Amri began training in 2020 and will undergo 7,000 hours of mentorship. Why it matters: This initiative addresses a critical gap in scientific infrastructure and expertise within Saudi Arabia, fostering self-sufficiency in research support and potentially establishing KAUST as a regional center for glassblowing consultation.
Michael Hickner, an Associate Professor from Penn State University, visited KAUST as part of the CRDF-KAUST-OSR Visiting Scholar Fellowship Program. Hickner specializes in Materials Science and Engineering, Chemistry, and Chemical Engineering. The visit was documented with photos by Meres J. Weche. Why it matters: Such programs foster international collaboration and knowledge exchange in science and engineering between KAUST and other leading institutions.
KAUST Professor Nikos Hadjichristidis leads the Polymer Synthesis Laboratory, collaborating with Yves Gnanou to manipulate macromolecules at the nanoscale. They employ anionic polymerization using high vacuum techniques, a specialized method requiring handmade glassware and careful control. The team is working on sustainable polymeric materials, including rethinking tire composition to improve recyclability and reduce pollution. Why it matters: This research contributes to developing more sustainable plastics and polymers, addressing a critical environmental challenge while advancing materials science in the region.
KAUST's Supply Chain Services implemented a Chemical Re-Use Program in February 2016 to encourage researchers to share surplus chemicals. Over 100 researchers have donated more than 3,000 bottles, with over 1,300 bottles reused across multiple divisions and centers. The Enterprise Reagent Manager (ERM) software helps researchers locate available chemicals. Why it matters: This initiative reduces chemical waste, saves costs and time associated with procurement, and promotes environmental sustainability within the university's research ecosystem.
KAUST researchers presented their work on stabilizing nanoparticle catalysts at the 252nd American Chemical Society Meeting & Exposition. The team devised a "molecular Scotch tape" using a silica gel support coated with a single molecule layer of soft material containing sulfur. This approach allows nanoparticles to stick to one side while leaving the other side free for catalysis, preventing aggregation without killing the catalyst. Why it matters: This innovation in catalyst stabilization could lead to more efficient and sustainable chemical processes, impacting various industries.
Scimagine is a KAUST-based startup that provides a cloud-based platform for managing and storing experimental data for material scientists. The platform allows researchers to store, manage, and share their data, as well as create scientific visuals. It addresses the problem of experimental data being hidden in PDF files and not easily searchable. Why it matters: This platform improves data accessibility and collaboration in materials science research, potentially accelerating discovery and innovation in the field.
A KAUST team discovered a simple method to fabricate microspheres using block copolymer self-assembly. The resulting particles have pH-responsive gates and a highly porous structure, granting them ultrahigh protein sorption capacity. The team leveraged their expertise in block copolymers and self-assembly to achieve this. Why it matters: This new method and the resulting particles have potential applications in biotechnology, medicine, and catalysis, advancing materials science in the region.