Innovating Across the Life Cycle of Macromolecular Materials

Polymers are ubiquitous in the modern world, and the demand for and production of plastic products continues to rise. Alternative approaches are critical in the transition from a dependence on petroleum feedstocks to the utilization of biomass building blocks towards the development of robust polymeric materials with exceptional mechanical function and thermal properties. I will share innovations to establish a life cycle management framework for polymer design, focusing on biomass building blocks derivable from lignin sources. Examples of performance-advantaged polymer materials, including thermoplastics and thermosets, will be described, with the potential to address the health impacts of petroleum-derived analogs; promote sustainable manufacturing; enable robust end-of-life valorization; and serve as functional matrices for composite design. Emerging research to establish key design rules connecting reprocessability, feedstock source, manufacturability, and performance also will be highlighted.

Historically, the chemical manufacturing of plastics has focused on key features, such as durability, low cost, and multifunctionality; however, these aspects also challenge current deconstruction and upgrading efforts to combat the plastics waste dilemma, particularly ‘real’ waste streams. I will overview fundamental challenges to plastics recycling. With this framework, I will highlight strategies designed to tackle the architectural complexity of plastics waste, address the influence of additives and contaminants in plastics waste deconstruction, and describe analytical methods and computational tools to probe polymer-catalyst interactions. Collectively, these vignettes provide insight into the interplay of architecture, formulation diversity, and form factor on plastics deconstruction and upgrading.