Development of new renewable polymers from limonene and curcumin following the green chemistry principles

Abstract

Polymeric materials derived from sustainable sources have been of great interest in recent years, being considered a viable alternative to conventional polymers derived from fossil sources. This fact is supported by the increasing consumption of polymeric materials, which, for the most part (derived from finite sources), have low recycling rates and limited life cycle. In this context, this project aims to use limonene and curcumin, both considered biomasses, as raw materials for obtaining novel monomers and polymers that enable circular economy, through the recovery of waste generated in economic activities. The use of intercrossing agents containing sulfur atoms has been widely employed in compounds with shape memory (vitrimer), which have the ability to be reshaped after the application of an external force, increasing the polymer lyfe cycle. Thus, the main of this project is to obtain renewable polymers with distinct mechanical, thermal, vitrimer, and luminescent properties, with potential for use in 3D printers. The syntheses of limonene-derived monomers, as well as their copolymers, will be carried out by photochemical reactions, which are considered green and efficient routes. Copolymerization with triallylcyanurate may result in the formation of thermosetting polymeric materials. In addition, the ability of transition metals Cu(II)/Zn(II) to form adaptive covalent bonds will be evaluated, which may result in the emergence of self-healing/ shape memory properties. Curcumin polymers will be obtained by thermal polymerization. These synthetic routes will be evaluated for their efficiency in adding value to raw materials, aiming to study the potential for production by the Brazilian industry. Moreover, theses polymeric materials derived from limonene and curcumin can also be applied in the development of printed electrodes. (AU)