Scientists have combined epoxy with a tough graphene foam and carbon nanotube scaffold to build a resilient epoxy composite that’s tougher and as conductive as other compounds but a lot lighter.
Epoxy combined with “ultrastiff” graphene foam is substantially tougher than pure epoxy and far more conductive than other epoxy composites while retaining the material’s low density. Researchers say it could improve upon epoxies in current use that weaken the material’s structure with the addition of conductive fillers.
By itself, epoxy is an insulator, and is commonly used in coatings, adhesives, electronics, industrial tooling, and structural composites. Scientists often add metal or carbon fillers for applications where conductivity is desired, like electromagnetic shielding.
But there’s a trade-off: More filler brings better conductivity at the cost of weight and compressive strength, and the composite becomes harder to process.
The solution, invented in the lab of Rice University chemist James Tour, replaces metal or carbon powders with a three-dimensional foam made of nanoscale sheets of graphene, the atom-thick form of carbon.
Tour and colleagues took their inspiration from projects to inject epoxy into 3D scaffolds including graphene aerogels, foams, and skeletons from various processes.
The new scheme makes much stronger scaffolds from polyacrylonitrile (PAN), a powdered polymer resin they use as a source of carbon, mixed with nickel powder. In the four-step process, they cold-press the materials to make them dense, heat them in a furnace to turn the PAN into graphene, chemically treat the resulting material to remove the nickel, and use a vacuum to pull the epoxy into the now-porous material.
“The graphene foam is a single piece of few-layer graphene,” Tour says. “Therefore, in reality, the entire foam is one large molecule. When the epoxy infiltrates the foam and then hardens, any bending in the epoxy in one place will stress the monolith at many other locations due to the embedded graphene scaffolding. This ultimately stiffens the entire structure.”
Tennis rackets and aerospace
The puck-shaped composites with 32 percent foam were marginally denser, but had an electrical conductivity of about 14 Siemens (a measure of conductivity, or inverse ohms) per centimeter, the researchers say. The foam didn’t add significant weight to the compound, but gave it seven times the compressive strength of pure epoxy.
Easy interlocking between the graphene and epoxy helped stabilize the structure of the graphene as well. “When the epoxy infiltrates the graphene foam and then hardens, the epoxy is captured in micron-sized domains of the graphene foam,” Tour says.
The lab upped the ante by mixing multiwalled carbon nanotubes into the graphene foam. The nanotubes acted as reinforcement bars that bonded with the graphene and made the composite 1,732 percent stiffer than pure epoxy and nearly three times as conductive, at about 41 Siemens per centimeter, far greater than nearly all of the scaffold-based epoxy composites reported to date, according to the researchers.
Tour expects the process will scale for industry. “One just needs a furnace large enough to produce the ultimate part,” he says. “But that is done all the time to make large metal parts by cold-pressing and then heating them.”
The material could initially replace the carbon-composite resins used to pre-impregnate and reinforce fabric used in materials such as aerospace structures and tennis rackets.
Visiting Rice student Xiao Han, a graduate student at Beihang University, and Rice graduate student Tuo Wang are co-lead authors of the paper, which appears in ACS Nano. Additional coauthors are from Rice and Tianjin University in China.
The Air Force Office of Scientific Research and the China Scholarship Council supported the research.
Source: Rice University