To accelerate self-healing speed of epoxy materials,epoxy-SbF5 cure was introduced into the healing chemistry.Due to the high activity of SbF5,a milder SbF5-ethanol complex with improved processability was prepared,but it was still quite active and cannot be encapsulated by conventional encapsulation techniques like in situ polymerization.Accordingly,a novel route was proposed.Hollow silica microcapsules were firstly synthesized via sol-gel technique,which were then steeped in ethanol solution of SbF5-ethanol complex under vacuum,allowing infiltration of the latter into the capsules.The optimal formulation for creating the hollow silica capsules was studied in detail.Moreover,the results of optical pyrometry demonstrated that the encapsulated chemical retained its high reactivity toward the epoxy.
It is a great pleasure for international colleagues in polymer science to celebrate Professor Fosong Wang on his 80th birthday. Professor Fosong Wang, a member of the Chinese Academy of Sciences, is a great polymer scientist, with over 300 publications and a few books. He is internationally recognized in his work on stereoregular polymers and electronically active polymers,
Self-healing polymers represent a class of materials with built-in capability of rehabilitating damages. The topic has attracted increasingly more attention in the past few years. The on-going research activities clearly indicate that self-healing polymeric materials turn out to be a typical multi-disciplinary area concerning polymer chemistry, organic synthesis, polymer physics, theoretical and experimental mechanics, processing, composites manufacturing, interfacial engineering, etc. The present article briefly reviews the achievements of the groups worldwide, and particularly the work carried out in our own laboratory towards strength recovery for structural applications. To ensure sufficient coverage, thermoplastics and thermosetting polymers, extrinsic and intrinsic self-healing, autonomic and non-autonomic healing approaches are included. Innovative routes that correlate materials chemistry to full capacity restoration are discussed for further development from bioinspired toward biomimetic repair.
