HBKU Showcases Innovative Approach To Self-Assembled Molecular 3D Printing

Doha, February 27 (QNA) - A research team at Hamad Bin Khalifa University’s (HBKU) Qatar Environment and Energy Research Institute (QEERI) has successfully demonstrated the world's first Self-Assembled Molecular 3D printing approach. This pioneering approach seamlessly integrates the concept of molecular self-assembly (the spontaneous organization of organic molecules) with additive manufacturing technology to produce a new class of hybrid metal/organic materials with unique properties. This achievement paves the way for the development of new devices and systems with advanced and augmented functions, such as a new generation of electronics, sensors, and solar cells. Being at the forefront of this field of research, HBKU aims at furthering the development of this technology for the international marketplace. Recently, HBKU entered into a research collaboration with the Massachusetts Institute of Technology (MIT) to jointly develop a full-scale system that utilizes this Self-Assembled Molecular 3D printing approach in real-world applications. Commenting on this achievement, Senior Planning and Research Director, Office of HBKU’s Vice President for Research (OVPR) Dr. Rachid Zaffou said: "Molecular Self-Assembly in 3D printing is a novel and disruptive approach that could define new frontiers. We are excited to collaborate with MIT to accelerate the development of this technology and collaborate toward building a full-scale system that can be used for practical applications." This research, led by Dr. Hicham Hamoudi, Founder of the Disruptive Technology research program at HBKU, was borne out of HBKU’s Thematic Research Grant Program, which is organized by OVPR. The innovative 3D printing method successfully passed its proof-of-concept stage, securing various patents in the process. It has also been recognized by the Commonwealth Scientific and Industrial Research Organization (CSIRO) as the first in the world demonstration of Self-Assembly molecular 3D printing. (QNA)