- Seo, Sungbaek;
- Lee, Dong Woog;
- Ahn, Jin Soo;
- Cunha, Keila;
- Filippidi, Emmanouela;
- Ju, Sung Won;
- Shin, Eeseul;
- Kim, Byeong‐Su;
- Levine, Zachary A;
- Lins, Roberto D;
- Israelachvili, Jacob N;
- Waite, J Herbert;
- Valentine, Megan T;
- Shea, Joan Emma;
- Ahn, B Kollbe
Marine mussels use catechol-rich interfacial mussel foot proteins (mfps) as primers that attach to mineral surfaces via hydrogen, metal coordination, electrostatic, ionic, or hydrophobic bonds, creating a secondary surface that promotes bonding to the bulk mfps. Inspired by this biological adhesive primer, it is shown that a ≈1 nm thick catecholic single-molecule priming layer increases the adhesion strength of crosslinked polymethacrylate resin on mineral surfaces by up to an order of magnitude when compared with conventional primers such as noncatecholic silane- and phosphate-based grafts. Molecular dynamics simulations confirm that catechol groups anchor to a variety of mineral surfaces and shed light on the binding mode of each molecule. Here, a ≈50% toughness enhancement is achieved in a stiff load-bearing polymer network, demonstrating the utility of mussel-inspired bonding for processing a wide range of polymeric interfaces, including structural, load-bearing materials.