Development of graphene with enhanced speed of high frequency signal transmission
- Date:
- May 8, 2019
- Source:
- DGIST (Daegu Gyeongbuk Institute of Science and Technology)
- Summary:
- Scientists have developed high frequency signal transmission line technology which maximizes carrier concentration of graphene using graphene-amorphous carbon junction structure.
- Share:
The DGIST Department of Information and Communication Engineering developed a graphene-based high-performance transmission line with an improved operating speed of electrons than using the existing metal in high-frequency. This is expected to contribute greatly to next generation's high-speed semiconductor and communication device with much faster processing speed than the existing one.
DGIST announced on Thursday, May 2 that Professor Jae Eun Jang's team researched the high frequency transmission characteristics of single-layer graphene in the Department of Information and Communication Engineering, and developed a high-performance, high-frequency transmission line that induced an increase of device concentration inside graphene. This result showed the characteristics of high frequency transmission with great improvement that can replace the metal used in the existing high-speed semiconductor processing, and its potential use as a transmission line of graphene is expected in the future.
Due to the high-integration and high speed of semiconductor devices, the resistance of metal wire in which signals among devices are transmitted has increased geometrically, reaching the limit of permissible current density. To resolve this issue, carbon-based nano structures such as graphene and carbon nano tube, which are regarded as the substitutes of existing metals, have drawn attention as next generation new materials.
However, graphene has a hexagonal array of carbon, with very thin thickness of 0.3nm, electric conductivity that is 100 times greater than copper, and electron mobility that is 100 times faster than silicon. It has thus been mentioned as an electronic material that can replace the existing metal and semiconductor materials. However, pure graphene has too low device concentration of 1012 cm-2 with thin structural characteristics of nanometer, which results in too high resistance of graphene.
In order to overcome such limitations, Professor Jang's team conducted a research to improve high frequency transmission characteristics of graphene by enhancing the device concentration inside graphene. By combining graphene and amorphous carbon, the team increased the device concentration of graphene and enhanced the electrical characteristics of graphene. The high frequency transmission of increased graphene was -8dB, which could be comparable to metal nano lines with hundreds of nano size.
The team also proved that defects inside graphene decrease the high frequency transmission of graphene and developed a new, stable doping technique that minimized internal defects. This new doping technique increased the device concentration of graphene by 2x 1013cm-2 and showed stable thermal properties and electrical characteristics.
The high frequency graphene transmission line developed by Professor Jang's research team displayed high signal transmission efficiency and stable operating characteristics, which can be applied to the metal wiring processing of the existing semiconductor industry as well as next generation integrated circuit.
Professor Jae Eun Jang in the Department of Information and Communication Engineering said "Along with device technology, transmission line is a very important technology in the semiconductor research field. We have developed a core base technology that can enhance the high frequency transmission of graphene that can be used as next generation transmission line. Thanks to the results of convergence research by experts in nano engineering, electronic engineering, and physics, we expect to use the graphene on high-frequency circuit such as MMIC and RFIC .
Story Source:
Materials provided by DGIST (Daegu Gyeongbuk Institute of Science and Technology). Note: Content may be edited for style and length.
Journal Reference:
- Jang-Won Kang, Bokyung Song, Wenjing Liu, Seong-Ju Park, Ritesh Agarwal, Chang-Hee Cho. Room temperature polariton lasing in quantum heterostructure nanocavities. Science Advances, 2019; 5 (4): eaau9338 DOI: 10.1126/sciadv.aau9338
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