Diamonds could make future electronics sparkle
Applying thin film diamond coatings at lower temperatures expands the options for electronic devices
A new method for creating thin films of diamonds could enhance future electronics.
In industrial and high-tech settings, diamonds are particularly valued for their hardness, optical clarity, smoothness, and resistance to chemicals, radiation and electrical fields.
For electronics applications, researchers dope diamonds in order to make them conductive, by introducing boron into the diamond manufacturing process.
In the past, it has been a challenge to instill electronic devices with diamond-like qualities by applying a doped diamond coating, or thin film. This is because the high temperatures required to apply a doped diamond thin film would destroy sensitive electronics, including biosensors, semiconductors, and photonic and optical devices.
Now, a team of researchers at Advanced Diamond Technologies, Inc., in Romeoville, Illinois say they have created thin films of boron-doped diamond at temperatures low enough (between 460-600°C) to coat many of these devices. This is described in detail in an Applied Physics Letters paper.
While low-temperature deposition of boron-doped diamond thin films is not conceptually new, the research team found no evidence in the literature of such diamond films that had both sufficient quality and manufacturing rates fast enough to be commercially useful.
Tweaking their own normal-temperature boron doping recipe by both lowering the temperature and adjusting the typical ratio of methane to hydrogen gas yielded a high quality film without appreciable change in conductivity or smoothness compared to diamond films made at higher temperatures. The researchers say more data and study is needed to better understand low-temperature opportunities.
Even so, by further optimising the recipe, the researchers expect to be able to deposit boron-doped diamond thin films at temperatures even lower than 400° C.
"The lower the deposition temperature, the larger number of electronic device applications we can enable," points out Hongjun Zeng of Advanced Diamond Technologies, Inc. "That will further expand the product categories for thin, smooth, conductive diamond coatings," Zeng he adds.
This work is described in detail in the article, "Low Temperature Boron Doped Diamond," by Hongjun Zeng et al in Journal of Applied Physics Letters, 102, 223108 (2013). http://dx.doi.org/10.1063/1.4809671
