Catalyst breaks sulfur–sulfur bonds to give new life to tired tyres

An image showing car tyres

Process recovers organic components that can become new elastomers

Researchers from Canada have demonstrated a mild chemical approach for reclaiming organic polymers from waste tyre rubber. Their Lewis acid-catalysed reductive silylation process could reduce the environmental impact of used sulfur-crosslinked elastomers.

‘The recovery of vulcanised rubbers is a major environmental problem, whose solution is still open,’ comments Carlos Scuracchio, who works on rubber recycling at the Federal University of São Carlos, Brazil. The high stability of vulcanised tyre rubber makes it challenging to recycle; toxic constituents may leach into the environment from used tyre stockpiles and fires at such locations can be dangerous, very polluting and difficult to arrest. 

Michael Brook from McMaster University, who led the team behind the new silylation process has first-hand experience of tyre fires. ‘About 15 years or 20 years ago, not far from where I live in Hamilton, there was a really bad tyre fire. The byproducts of that were not good news for the local environment.’ 

Now, Brook’s team has shown that hydrosilanes, catalysed by B(C6F5)3, can effectively reduce sulfur–sulfur bonds in complex sulfur-crosslinked tyre rubbers in yields of up to 90%. They demonstrated their process on bicycle inner tubes, solid tyres and tyre crumb, and the resulting polymeric, silyl-protected thiolated oils were straightforward to separate by filtration or centrifugation. The team also showed they could radically or oxidatively crosslink the resulting oils to generate new elastomers, from which they created a new toy tyre as a proof of concept.

A scheme showing how the reductive silylation of RS-SR bonds to silyl thio ethers using a variety of hydrosilicones occurs in the presence of B(C6F5)3
Source: © Michael Brook/McMaster University
Reductive silylation of RS–SR bonds to silyl thio ethers using a variety of hydrosilicones in the presence of B(C6F5)3 could be developed into a recycling process for car tyres

‘We were surprised that you could actually get the rubber to dissolve and be converted back to liquid polymeric materials. I didn’t expect it to happen quite as well as it did,’ explains Brook. He says there is ‘really very little out there in the literature’ on the depolymerisation of sulfur-cured rubbers, and that ‘if there were a commercially viable process, people would be using it’. However, with 10wt% of ‘quite expensive’ catalyst being required to reduce the used tyre rubber, Brook clarifies that ‘there’s no way in my view that today this is a commercial process. But I think it opens the door into thinking about different ways to degrade the rubbers to make useful polymers again.’ The team are already optimising the process to reduce the quantity of catalyst it requires.

‘Most rubber recycling techniques generate materials that are difficult to mould and process and have quite different properties from the original raw materials,’ adds Scuracchio. ‘At this point, a very interesting part of the work is that the rubber can be processed without worrying about possible contamination, and the material produced is a rheologically simple oil capable of being moulded and transformed back into a solid product. This factor makes the method very promising in the field of rubber recycling.’

References: This article is open access S Zheng et al, Green Chem., 2019, DOI: 10.1039/c9gc03545a

Royal Society of Chemistry - ChemistryWorld
BY RUTH ZADIK 17 DECEMBER 2019

 

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McMaster University - Faculty of Science | Chemistry & Chemical Biology