Researchers from Nanjing University in China have developed a method to make large graphene films free of any wrinkles. The ultra-smooth films could enable large-scale production of electronic devices that harness the unique physical and chemical properties of graphene and other 2D materials.
Chemical vapor deposition (CVD) is the best-known method for making high-quality graphene sheets. It typically involves growing graphene by pumping methane gas onto copper substrates heated to temperatures around 1,000 °C, and then transferring the graphene to another surface such as silicon. But some of the graphene sticks to the copper surface, and as the graphene and copper expand and contract at different rates, wrinkles form in the graphene sheets. Such wrinkles often present hurdles for charge carriers and lower the film’s conductivity. Other researchers have tried to reduce wrinkles using low growth temperatures or special copper substrates, but the wrinkles have proven difficult to eliminate entirely, according to Libo Gao, a physicist at Nanjing University.
Gao and his colleagues found that carefully harnessing protons during CVD can fully flatten the wrinkles. They used a method called plasma-enhanced CVD, in which reactive plasma is introduced into the growth chamber, allowing graphene growth at a lower temperature of 650 °C, an important step toward growing graphene directly on other substrates without having to transfer it.
The team used a plasma of hydrogen gas, which contains a mix of hydrogen atoms, electrons, and protons. Only the electrons and protons permeate the graphene films, recombining underneath to form hydrogen gas between the graphene and copper substrate. These gas pockets keep graphene from sticking to the copper, giving wrinkle-free graphene films.
It takes a few minutes to grow ultra-flat graphene sheets on a roughly 10-cm copper substrate, and the method could easily be used on larger substrates, Gao says. The proton-assisted method could also be used to grow other wrinkle-free 2D materials. What’s more, Gao says, the method could lead to a new hydrogen storage system in which the gas is stored between layers of 2D materials - an idea his team is now exploring.
One limitation of the process, says Zhongfan Liu, a physical chemist at Peking University, is that the decoupling of graphene from the substrate results in graphene growing in different directions, yielding a multicrystalline film instead of a single-crystal film. Single-crystal films produce higher-quality devices. Nonetheless, he adds “this advance is critical for the killer applications of graphene in high-performance electronics and optoelectronics because of its good compatibility with wafer process and the improved properties on a large scale.”