Synthesis of homo- and copolyesters containing divanillic acid, 1,4-cyclohexanedimethanol, and alkanediols and their thermal and mechanical properties

Synthesis of divanillic acid-based aromatic polyamides with linear and branched side-chains and the effect of side-chain structure on thermal and mechanical properties

Divanillic acid (DVA)-based aromatic polyamides (PAs) consisting of DVA with linear (methyl, butyl, hexyl, and octyl groups) or branched (isopropyl and isobutyl groups) side chains and 4,4'-methyldianillin were synthesized as high-performance and ultra-high-performance biomass plastics. The DVA PAs were amorphous with high thermal stability (decomposition temperature of ca. 380 °C). The glass transition temperature (Tg) of the DVA PAs depended on the side-chain composition in a linear manner, indicating the PA main chain possessed a random structure. The polymers were pressed to form melt-pressed films. The DVA PAs with a higher content of shorter side chains exhibited both higher Tg and tensile strength than those of polymers with a lower content of shorter side chains. The PAs exhibited Tg in the range of ca. 150-253 °C. The branched PA with isopropyl side chains exhibited the highest Tg of 253 °C and highest tensile strength of 63 MPa among the DVA PAs. The PAs with isopropyl side chains and some linear side chains (methyl/hexyl combination) exhibited high tensile strength of approximately 60-70 MPa; however, their Tg varied from 170 to 253 °C. The branched PA exhibited the highest Tg, tensile strength, and Young's modulus of the polymers. The thermal stability and mechanical properties of the PAs were tuned by their side-chain structure and composition.