Chemical Structure of the Gels (A) Schematic representation of HPPRx and HPPul used in this study. (B) Chemical structures of the PRx-PB (x) gel, Pul-PB (x) gel, PRx-CC (x) gel, and pAAm (x) gel used in this study. Here, x represents the mol % content of cross-linker units in the vinyl polymerization.
Before we have self-healing cars or buildings, we need strong materials that can fully self-repair in water-free environments. Self-healing materials work very well if they are soft and wet, but research groups have found that the ability to self-repair diminishes as materials dry out. Scientists at Osaka University are beginning to bridge this gap with rigid materials that can repair 99% of a cut on the surface in semi-dry conditions. They present their prototypes, which are the first to combine physical and chemical approaches to self-healing, on November 10 in Chem.
“The combination of physical and chemical self-healing enables materials to exhibit rapid and efficient self-healing even in a dried, hard state,” says senior author Akira Harada, a supramolecular polymer chemist at Osaka University. “Only a small amount of water vapor is needed to facilitate self-healing in the dried film state. In other words, water serves as a non-toxic glue in the self-healing process,” adds co-author Yoshinori Takashima, an associate professor at Osaka University.
Material engineers can physically embed the material with microcapsules or pathways filled with healing agents or build the material by using molecules, eg polyrotaxane, that change shape in response to damage, ie stress relaxation. Chemical self-healing materials use reversible bonds ranging from reversible chemical reactions to intermolecular interactions such as H-bonding.
Harada’s lab combined physical and chemical self-healing mechanisms in their materials by using polyrotaxane as a backbone structure cross-linked by reversible interactions, in this case between boronic acid and diols. The polyrotaxane structure enables stress relaxation in recovery from a shallow dent, and the reversible nature of the bonds enables chemical self-healing from a deep cut. The combined approach allowed the materials to recover up to 80% strength within 10 minutes (without the combination, the materials could repair only up to 30% of their strength after an hour).
“Recent research on supramolecular polymeric materials has demonstrated that smart design leads to smart function on a macroscopic scale,” says Masaki Nakahata, an assistant professor in engineering science at Osaka University. “Polymeric materials, both tough and self-healable, can open up a new frontier in materials science.” Applications: external coatings of cars and buildings to medical applications, such as self-healing adhesives and resins. They plan to continue working on the creation of a hard material that can self-heal under ambient conditions without the addition of any external cues.
http://www.cell.com/chem/fulltext/S2451-9294(16)30158-9
http://phys.org/news/2016-11-self-healing-materials-semi-dry-conditions.html
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