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'Direct writing' of diamond patterns from graphite a potential technological leap

Date:
November 5, 2014
Source:
Purdue University
Summary:
What began as research into a method to strengthen metals has led to the discovery of a new technique that uses a pulsing laser to create synthetic nanodiamond films and patterns from graphite, with potential applications from biosensors to computer chips.
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What began as research into a method to strengthen metals has led to the discovery of a new technique that uses a pulsing laser to create synthetic nanodiamond films and patterns from graphite, with potential applications from biosensors to computer chips.

"The biggest advantage is that you can selectively deposit nanodiamond on rigid surfaces without the high temperatures and pressures normally needed to produce synthetic diamond," said Gary Cheng, an associate professor of industrial engineering at Purdue University. "We do this at room temperature and without a high temperature and pressure chamber, so this process could significantly lower the cost of making diamond. In addition, we realize a direct writing technique that could selectively write nanodiamond in designed patterns."

The ability to selectively "write" lines of diamond on surfaces could be practical for various potential applications including biosensors, quantum computing, fuel cells and next-generation computer chips.

The technique works by using a multilayered film that includes a layer of graphite topped with a glass cover sheet. Exposing this layered structure to an ultrafast-pulsing laser instantly converts the graphite to an ionized plasma and creates a downward pressure. Then the graphite plasma quickly solidifies into diamond. The glass sheet confines the plasma to keep it from escaping, allowing it to form a nanodiamond coating.

"These are super-small diamonds and the coating is super-strong, so it could be used for high-temperature sensors," Cheng said.

Research findings are detailed in a paper that appeared online in the Nature journal Scientific Reports. The paper was authored by former Purdue doctoral students Yuefeng Wang, Yingling Yang, Ji Li and Martin Y. Zhang; postdoctoral research associate Jiayi Shao; doctoral students Qiong Nian and Liang Tang; and Cheng.

The researchers made the discovery while studying how to strengthen metals using a thin layer of graphite and a nanosecond-pulsing laser. A doctoral student noticed that the laser was either causing the graphite to disappear or turn semi-transparent.

"The black coating of graphite was gone, but where did it go?" Cheng said.

Subsequent research proved the graphite had turned into diamond. The Purdue researchers have named the process confined pulse laser deposition (CPLD).

The research team confirmed that the structures are diamond using a variety of techniques including transmission electron microscopy, X-ray diffraction and the measurement of electrical resistance.

A U.S. patent application has been filed on the concept through the Purdue Office of Technology Commercialization. More research is needed to commercialize the technique, Cheng said.


Story Source:

Materials provided by Purdue University. Original written by Emil Venere. Note: Content may be edited for style and length.


Journal Reference:

  1. Qiong Nian, Yuefeng Wang, Yingling Yang, Ji Li, Martin Y. Zhang, Jiayi Shao, Liang Tang, Gary J. Cheng. Direct Laser Writing of Nanodiamond Films from Graphite under Ambient Conditions. Scientific Reports, 2014; 4: 6612 DOI: 10.1038/srep06612

Cite This Page:

Purdue University. "'Direct writing' of diamond patterns from graphite a potential technological leap." ScienceDaily. ScienceDaily, 5 November 2014. <www.sciencedaily.com/releases/2014/11/141105203549.htm>.
Purdue University. (2014, November 5). 'Direct writing' of diamond patterns from graphite a potential technological leap. ScienceDaily. Retrieved March 18, 2024 from www.sciencedaily.com/releases/2014/11/141105203549.htm
Purdue University. "'Direct writing' of diamond patterns from graphite a potential technological leap." ScienceDaily. www.sciencedaily.com/releases/2014/11/141105203549.htm (accessed March 18, 2024).

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