This Leading Engineering for America's Prosperity, Health, and Infrastructure (LEAP-HI) project promises to dramatically reduce the cost of manufacturing high-strength composite materials. Living systems achieve form and function in ways that have little resemblance to modern manufacturing: think digits of a hand, the veins of a leaf, or the seeds of a dandelion that disperse themselves in the wind. Using nature as a model, the research will develop a new technology for the processing of plastics and composites, critical elements in structures like aircraft, automobiles and wind turbine blades, where light weight and high-strength are required. Current manufacturing of these materials is costly, to the large amounts of energy required. Drawing inspiration from living systems, this fundamental research project will result in new plastic materials that require only small initial energy input to trigger the entire manufacturing process and dramatically reduce environmental impact. This new, more efficient method has significant potential to impact and dramatically improve U.S. economic competitiveness in the critical area of composites manufacturing.
This award will enable highly collaborative, interdisciplinary research to develop a new manufacturing platform for structural polymers and composites based on an autocatalytic (self-propagating) polymerization reaction occurring in a system undergoing reaction and diffusion of its components. The system uses the exothermic release of energy to provide a positive feedback to the reaction. In turn, this stimulates further exothermic energy release, and a self-propagating reaction front that rapidly moves through the material ? a process called frontal polymerization. Once triggered, the reaction progresses with zero-energy input. The self-sustained propagation of a reaction wave through the material gives rise to entirely new ways of manufacturing high performance composites using rapid, energy efficient methods at greatly reduced costs, including 3D printing of thermosetting polymers and composites. Controlling the reaction wave by simple thermal perturbations gives rise to symmetry breaking events that can enable complex, emergent (morphogenic) pattern formation. Moreover, our biologically inspired concepts for manufacturing provide an ideal platform to inspire and educate the next generation of entrepreneurs, students, postdoctoral researchers, as well as the general public.
This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.
