The Army Corps of Engineers will work with Prof. Tour and his collaborators at Rice University through a $5.2 million, four-year grant to expand the process that turns waste into graphene through flash Joule heating, to additional materials as well. Among the initiatives is a strategy to recover cobalt, lithium and other elements through the process developed by Tour’s group.
The grant through a Department of the Interior Cooperative Research and Development Agreement will allow the Rice-based team to extend the impact of its discovery that flashing food waste and other trash with a high-voltage jolt of electricity turns it into graphene. Through further experiments, the team realized the process could do much more. We’re pushing the idea that flash Joule heating can go way beyond just graphene, Tour said.
The work will incorporate molecular models by Rice materials theorist Boris Yakobson and former postdoctoral researcher Yufeng Zhao, now an assistant professor at Corban University in Salem, Oregon, to provide solid theoretical footing for new discoveries. Jian Lin, also a former Rice postdoctoral researcher and now an associate professor at the University of Missouri, will write machine-learning code to streamline the flash process.
Tour’s lab has reported success at recycling pyrolyzed ash from plastic waste into graphene for improving concrete and other composites as well as flashing dichalcogenides from semiconductors to metallic materials. He said the lab’s process to reclaim metals from used batteries is patented, and a detailed study is forthcoming.
There’s already interest in the environmental community over urban element mining, so finding a way to do it efficiently and in bulk will be of great importance going forward, Tour said. We have a lot of other ideas for ways flash Joule heating can help.
The original experiments to convert food waste involved packing carbon-containing waste between two electrodes in a tube and sending enough power through to raise its temperature to about 5,000 degrees Fahrenheit in 10 milliseconds.
Anything that wasn’t carbon was emitted as gas, leaving behind turbostratic graphene, a configuration of the 2D material in which layers are offset enough to weaken their bonds, making the flakes soluble, and thus easier to use in composite materials.
The lab has since discovered that by "playing" with the parameters, it can fine-tune the conversion of a variety of waste materials into products of value.