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Boosting 5G technology

Date:
November 21, 2019
Source:
U.S. Army Research Laboratory
Summary:
A new project may boost 5G and mm-Wave technologies, improving military communications and sensing equipment.
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An Army-funded project may boost 5G and mm-Wave technologies, improving military communications and sensing equipment.

Carbonics, Inc., partnered with the University of Southern California to develop a carbon nanotube technology that, for the first time, achieved speeds exceeding 100GHz in radio frequency applications. The milestone eclipses the performance -- and efficiency -- of traditional Radio Frequency Complementary Metal-Oxide Semiconductor, known as RF-CMOS technology, that is ubiquitous in modern consumer electronics, including cell phones.

"This milestone shows that carbon nanotubes, long thought to be a promising communications chip technology, can deliver," said Dr. Joe Qiu, program manager, solid state and electromagnetics at the Army Research Office. "The next step is scaling this technology, proving that it can work in high-volume manufacturing. Ultimately, this technology could help the Army meet its needs in communications, radar, electronic warfare and other sensing applications."

The research was published in the journal Nature Electronics.

The work, funded by ARO, an element of U.S. Army Combat Capabilities Development Command's Army Research Laboratory, is a part of a Small Business Technology Transfer Program. The program focuses on feasibility studies leading to prototype demonstration of technology for specific applications.

For nearly two decades, researchers have theorized that carbon nanotubes would be well suited as a high-frequency transistor technology due to its unique one-dimensional electron transport characteristics. The engineering challenge has been to assemble the high-purity semiconducting nanotubes into densely aligned arrays and create a working device out of the nanomaterial.

Carbonics, a venture backed start-up, and USC, successfully overcame this challenge. Projections based on scaling single carbon nanotube device metrics suggest the technology could ultimately far exceed the top-tier incumbent RF technology, Gallium Arsenide.

Carbonics employs a deposition technology called ZEBRA that enables carbon nanotubes to be densely aligned and deposited onto a variety of chip substrates including silicon, silicon-on-insulator, quartz and flexible materials. This allows the technology to be directly integrated with traditional CMOS digital logic circuits, overcoming the typical problem of heterogeneous integration.

"With this exciting accomplishment, the timing is ripe to leverage our CMOS-compatible technology for the 5G and mm-Wave defense communication markets," said Carbonics' CEO Kos Galatsis. "We are now engaged in licensing and technology transfer partnerships with industry participants, while we continue to advance this disruptive RF technology."


Story Source:

Materials provided by U.S. Army Research Laboratory. Note: Content may be edited for style and length.


Journal Reference:

  1. Christopher Rutherglen, Alexander A. Kane, Philbert F. Marsh, Tyler A. Cain, Basem I. Hassan, Mohammed R. AlShareef, Chongwu Zhou, Kosmas Galatsis. Wafer-scalable, aligned carbon nanotube transistors operating at frequencies of over 100 GHz. Nature Electronics, 2019; 2 (11): 530 DOI: 10.1038/s41928-019-0326-y

Cite This Page:

U.S. Army Research Laboratory. "Boosting 5G technology." ScienceDaily. ScienceDaily, 21 November 2019. <www.sciencedaily.com/releases/2019/11/191121151215.htm>.
U.S. Army Research Laboratory. (2019, November 21). Boosting 5G technology. ScienceDaily. Retrieved November 2, 2024 from www.sciencedaily.com/releases/2019/11/191121151215.htm
U.S. Army Research Laboratory. "Boosting 5G technology." ScienceDaily. www.sciencedaily.com/releases/2019/11/191121151215.htm (accessed November 2, 2024).

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