Robust and dynamic underwater adhesives enabled by catechol-functionalized poly(disulfides) network

A robust underwater adhesive material is achieved by coupling natural thioctic acid with mussel-inspired iron-catechol chemistry, showing a high-strength, tunable and reusable adhesion to diverse surfaces. Developing molecular approaches to the creation of robust and water-resistant adhesive materials promotes a fundamental understanding of interfacial adhesion mechanisms as well as future applications of biomedical adhesive materials. Here, we present a simple and robust strategy that combines natural thioctic acid and mussel-inspired iron-catechol complexes to enable ultra-strong adhesive materials that can be used underwater and simultaneously exhibit unprecedentedly high adhesion strength on diverse surfaces. Our experimental results show that the robust crosslinking interaction of the iron-catechol complexes, as well as high-density hydrogen bonding, are responsible for the ultra-high interfacial adhesion strength. The embedding effect of the hydrophobic solvent-free network of poly(disulfides) further enhances the water-resistance. The dynamic covalent poly(disulfides) network also makes the resulting materials reconfigurable, thus enabling reusability via repeated heating and cooling. This molecule-engineering strategy offers a general and versatile solution to the design and construction of dynamic supramolecular adhesive materials.

Automated summary

A robust underwater adhesive material is achieved by coupling natural thioctic acid with mussel-inspired iron-catechol chemistry, showing high-strength, tunable, and reusable adhesion to diverse surfaces. The strategy combines natural thioctic acid and mussel-inspired iron-catechol complexes to enable ultra-strong adhesive materials that can be used underwater and exhibit unprecedentedly high adhesion strength on diverse surfaces. The robust crosslinking interaction of the iron-catechol complexes and high-density hydrogen bonding contribute to the ultra-high interfacial adhesion strength.