RESEARCHERS DISCOVER A RUBBER AND CATALYST THAT TOGETHER CREATE FLEXIBLE, REPAIRABLE, SUSTAINABLE OBJECTS

RESEARCHERS DISCOVER A RUBBER AND CATALYST THAT TOGETHER CREATE FLEXIBLE, REPAIRABLE, SUSTAINABLE OBJECTS 

Flinders University Associate Professor Justin Chalker announced in the May issue of Chemical Science (The Royal Society of Chemistry) DOI the creation of self-repairing rubber, or super-adhesive made entirely from waste materials. Researchers have discovered a new kind of rubber and catalyst that together can be used with low energy consumption to make flexible, repairable, sustainable objects, including car tires. The new rubber material, made from cheap and plentiful industrial waste products sulfur, canola cooking oil and dicyclopentadiene (DCPD) from petroleum refining, can be completely repaired and returned to its original strength in minutes, even at room temperature, with an amine catalyst. The new type of rubber can be seamlessly repaired if damaged, and can also be recycled, says research leader Professor Chalker, whose team's breakthrough findings are described in international journal Chemical Science. The amine catalyst used to trigger the reaction that causes the rubber to self-repair occurs within minutes in some cases, and it is all done at room temperature, scientists say. "This study reveals a new concept in the repair, adhesion and recycling of sustainable rubber," says Associate Professor Chalker, adding too many plastics, rubbers and ceramics are not recyclable. Each year in Australia, the equivalent of 48 million tires reach the end of their life, and only 16 percent of these are domestically recycled. Around two-thirds of used tires in Australia end up in landfill, are stockpiled, illegally dumped or have an unknown fate. This represents both a waste of resources and creates health and environmental issues. Each passenger car tire contains approximately 1.5 kg of steel, 0.5 kg of textiles and 7 kg of rubber. "It is exciting to see how the underlying chemistry of these materials has such wide potential in recycling, next-generation adhesives, and additive manufacturing." Researchers from the Chalker Laboratory at the Flinders University Institute for Nanoscale Science and Technology, with University of Liverpool and University of Western Australia colleagues, say the new rubber can be used as a "latent adhesive." "The rubber bonds to itself when the amine catalyst is applied to the surface. The adhesion is stronger than many commercial glues," says University of Liverpool researcher, Dr.Tom Hasell. "The polymer is also resistant to water and corrosion." Rubber bricks made out of this polymer can be chemically joined by applying the catalyst. "In some cases, the amine catalyst causes the rubber to bond in just minutes, and it can be done at room temperature," explains Flinders University lead author, Sam Tonkin. "The rubber can also be used as a latent adhesive, where it bonds to the surface of another piece of rubber when the amine catalyst is applied. "Basically the rubber is not 'sticky' until the catalyst is applied." In addition to the highly useful practical applications, the new paper gives detailed fundamental studies on the mechanisms of the rubber repair.
https://youtu.be/d4nHI_xGxzA

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