image: Method for coherent detection using a resonant tunneling diode (RTD). When the operating voltage of the RTD Vo is set within the negative differential conductance (NDC) region, the RTD oscillates, which enhances the detected power compared with that from conventional direct detection. Here, injection-locking helps to synchronize the RTD oscillation with the received signal. As a result, coherent detection of terahertz waves can be achieved with a single RTD. view more
Credit: Osaka University
Osaka, Japan - An Osaka University research team has introduced a new terahertz detector that allows extremely rapid wireless data communication and highly sensitive radar by using a frequency range that has previously been very difficult to work with. Their approach combined sensitive electronics and a novel method for handling high frequencies to achieve the long-sought goal of using terahertz radiation for sending and receiving wireless data. The record 30 gigabit per second real-time error-free transmission they obtained may lead the way for next-generation (6G) cellular network technology.
Wireless data is in great demand. Not only do mobile phones need high speeds to stream videos on the go, but some people living in rural areas rely entirely on wireless for their home broadband connections. Terahertz radiation—electromagnetic waves with frequencies around 1012 cycles per second—has long been tempting scientists and cell phone companies alike. The high frequency of terahertz radiation would allow more data to be transmitted per second, compared with the current standard of about 800 MHz. However, a practical terahertz receiver has remained elusive, for two main reasons. First, the electromagnetic oscillations are just too fast for conventional electronics to handle, and both the terahertz oscillator and detector have poor efficiency. Second, the thermal noise of the room-temperature detector obscures the received signals above.
Now, researchers at Osaka University have invented a novel receiver that not only overcomes these obstacles, it also set the record for the fastest error-free real-time transmission speed to date. They used a special electronic component called a resonant tunneling diode. In contrast with normal electronics - for which the current always increases at larger voltages - in a resonant tunneling diode, there is a specific "resonant" voltage that yields the peak current. Thus, there exists a region in which the current actually falls with increasing voltage. This nonlinear behavior allows the scientists to synchronize the rapid received terahertz signals with an internal electronic oscillator in the device, and then separate the data from the carrier wave. In the end, the sensitivity was enhanced by a factor of 10,000. "Among all electronic-based systems, ours achieved the highest error-free wireless transmission data rate," says first author Yousuke Nishida.
Cell phone towers are not the only places you might find terahertz radiation in the future. "This technology can be put to work in a wide range of applications, in addition to next-generation 6G wireless communication. These include spectroscopic sensing, non-destructive inspection, and high-resolution radar," adds corresponding author Masayuki Fujita.
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The article, "Terahertz coherent receiver using a single resonant tunnelling diode," was published in Scientific Reports at DOI: https://doi.org/10.1038/s41598-019-54627-8.
About Osaka University
Osaka University was founded in 1931 as one of the seven imperial universities of Japan and now has expanded to one of Japan's leading comprehensive universities. The University has now embarked on open research revolution from a position as Japan's most innovative university and among the most innovative institutions in the world according to Reuters 2015 Top 100 Innovative Universities and the Nature Index Innovation 2017. The university's ability to innovate from the stage of fundamental research through the creation of useful technology with economic impact stems from its broad disciplinary spectrum.
Website: https://resou.osaka-u.ac.jp/en/top
Journal
Scientific Reports