23-Jul-2015 - American Institute of Physics (AIP)

An easy, scalable and direct method for synthesizing graphene in silicon microelectronics

Korean researchers grow 4-inch diameter, high-quality, multi-layer graphene on desired silicon substrates

In the last decade, graphene has been intensively studied for its unique optical, mechanical, electrical and structural properties, but most graphene fabrication methods are not compatible with silicon microelectronics, thus blocking graphene's leap from potential wonder material to actual profit-maker.

Now researchers from Korea University, in Seoul, have developed an easy and microelectronics-compatible method to grow graphene and have successfully synthesized wafer-scale (four inches in diameter), high-quality, multi-layer graphene on silicon substrates. The method is based on an ion implantation technique, a process in which ions are accelerated under an electrical field and smashed into a semiconductor. The impacting ions change the physical, chemical or electrical properties of the semiconductor.

In a paper published in Applied Physics Letters, the researchers describe their work, which takes graphene a step closer to commercial applications in silicon microelectronics.

"For integrating graphene into advanced silicon microelectronics, large-area graphene free of wrinkles, tears and residues must be deposited on silicon wafers at low temperatures, which cannot be achieved with conventional graphene synthesis techniques as they often require high temperatures," said Jihyun Kim, the team leader and a professor in the Department of Chemical and Biological Engineering at Korea University. "Our work shows that the carbon ion implantation technique has great potential for the direct synthesis of wafer-scale graphene for integrated circuit technologies."

"In silicon microelectronics, graphene is a potential contact electrode and an interconnection material linking semiconductor devices to form the desired electrical circuits," said Kim. "This renders high processing temperature undesirable, as temperature-induced damage, strains, metal spiking and unintentional diffusion of dopants may occur."

Thus, although the conventional graphene fabrication method of chemical vapor deposition is widely used for the large-area synthesis of graphene on copper and nickel films, the method is not suited for silicon microelectronics, as chemical vapor deposition would require a high growth temperature above 1,000 degrees Celsius and a subsequent transfer process of the graphene from the metallic film to the silicon.

"The transferred graphene on the target substrate often contains cracks, wrinkles and contaminants," said Kim. "Thus, we are motivated to develop a transfer-free method to directly synthesize high quality, multilayer graphene in silicon microelectronics."

Kim's method relies on ion implantation, a microelectronics-compatible technique normally used to introduce impurities into semiconductors. In the process, carbon ions were accelerated under an electrical field and bombarded onto a layered surface made of nickel, silicon dioxide and silicon at the temperature of 500 degrees Celsius. The nickel layer, with high carbon solubility, is used as a catalyst for graphene synthesis. The process is then followed by high temperature activation annealing (about 600 to 900 degrees Celsius) to form a honeycomb lattice of carbon atoms, a typical microscopic structure of graphene.

Kim explained that the activation annealing temperature could be lowered by performing the ion implantation at an elevated temperature. Kim and his colleagues then systematically studied the effects of the annealing conditions on the synthesis of high-quality, multi-layer graphene by varying the ambient pressure, ambient gas, temperature and time during the treatment.

According to Kim, the ion implantation technique also offers finer control on the final structure of the product than other fabrication methods, as the graphene layer thickness can be precisely determined by controlling the dose of carbon ion implantation.

"Our synthesis method is controllable and scalable, allowing us to obtain graphene as large as the size of the silicon wafer [over 300 millimeters in diameter]," Kim said.

The researchers' next step is to further lower the temperature in the synthesis process and to control the thickness of the graphene for manufacturing production.

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  • ion implantation
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