This story is featured in the Asia Research News 2021 magazine. Read in ISSUU (above) or full text and images below.
Elastomers are the soft, elastic materials, like gels and rubbers, that are found in automobile and airplane parts, in sports equipment, and are used to protect precision machinery and buildings against vibrations. Scientists now want to make them thinner and tougher, without losing elasticity. Nagoya University materials engineer Yukikazu Takeoka and colleagues reviewed the most recent efforts towards improving elastomers for the journal Science and Technology of Advanced Materials.
“Our review gives hints about the kind of molecular thinking that needs to go into making elastomers tougher,” says Takeoka.
Different kinds of bonds can link elastomer chains together, changing how the material behaves.
Elastomers are made of many long molecular chains of repeating subunits. They can undergo large deformations when stretched, returning to their original shape when the tension is released. They can do this because their molecular chains have enough mobility to stretch and crunch up.
Elasticity and overall toughness depend on the interactions between the molecular chains inside the material. Scientists have been working on controlling how chains link together and interact in order to change elastomers’ mechanical properties.
Takeoka and his team from Nagoya University’s Department of Molecular and Macromolecular Chemistry explain that elastomers can be made tougher by introducing strong hydrogen or ionic bonds that can reversibly link elastomer chains together. These reversible bonds attach and detach from the elastomer chains as the material deforms. Scientists have used hydrogen bonds to fabricate strong hydrogels that can deform up to 600% and return to their original state within three minutes at 37°C or a few seconds at 50°C.
Elastomer chains can also be linked through ring-like cyclic molecules, giving linked chains a large degree of flexibility and improved toughness. For example, scientists mixed solutions of polyethylene glycol and cyclic alpha-cyclodextrin in water to make slide-ring molecules, which they then used to fabricate a very flexible elastomer.
Takeoka and his colleagues suggest that further combining elastomers linked by reversible bonds with moving cyclic molecules could lead to even tougher elastomers with better elongation. “It’s critical to examine molecular behaviour in detail while designing polymer materials,” says Takeoka.
Further information
Assoc Prof Yukikazu Takeoka
[email protected]
Department of Molecular Design & Engineering
Nagoya University
Dr Yoshikazu Shinohara
[email protected]
Science and Technology of Advanced Materials
National Institute for Materials Science
