Litcius/Paper detail

Review on Research Progress on Bio-Based Self-Healing Polyurethane

Hongyu Feng, Yuli Wang, Ting Zhang, Jiangbo Wang, Zhixin Jia, Shaohua Jiang, Xiaoshuai Han

2025ACS Materials Letters10 citationsDOI

Abstract

Self-healing polyurethane (SHPU) shows great potential in enhancing materials’ durability and sustainability, yet balancing robust mechanical properties with efficient self-healing under mild conditions remains challenging. Conventional approaches often sacrifice strength or healing ability. This Review focuses on the key role of biomass-derived materials, including lignin, cellulose, chitosan, and vegetable oils, in resolving this conflict. Acting as dynamic network modifiers, multifunctional enhancers, and microstructural regulators, they enable sacrificial bonding, microphase separation, and improved chain mobility. Biomass-based SHPUs can achieve over 90% self-healing efficiency at room temperature while maintaining strength and toughness and even incorporate additional functions like flame retardancy or conductivity. Moreover, biomass enhances sustainability by reducing fossil resource dependence and promoting recyclability. Despite challenges in performance consistency and raw material variability, molecular engineering offers a promising path toward high-performance, sustainable SHPUs for advanced manufacturing and a circular economy.

Topics & Concepts

ToughnessPolyurethaneDurabilityMaterials scienceRaw materialSustainabilityConsistency (knowledge bases)Resource efficiencyMechanical strengthProcess engineeringMaterial efficiencyFossil fuelEngineeringManufacturing engineeringForensic engineeringResource (disambiguation)Composite materialKey (lock)Biochemical engineeringCompressive strengthAutomotive industryBiomass (ecology)New product developmentProduct (mathematics)CombustionMechanical engineeringNanotechnologyPolymer composites and self-healingbiodegradable polymer synthesis and propertiesElectrospun Nanofibers in Biomedical Applications