New test reveals purity of graphene: Terahertz waves used to spot contaminants

Rice and Osaka researchers have come up with a simple method to find contaminants on atom-thick graphene. By putting graphene on a layer of indium phosphide, which emits terahertz waves when excited by a laser pulse, they can measure and map changes in its electrical conductivity. Credit: Rice and Osaka universities

 http://phys.org/news/2014-08-reveals-purity-graphene-terahertz-contaminants.html#jCp

Graphene may be tough, but those who handle it had better be tender. The environment surrounding the atom-thick carbon material can influence its electronic performance, according to researchers at Rice and Osaka universities who have come up with a simple way to spot contaminants.

Because it's so easy to accidently introduce impurities into graphene, labs led by physicists Junichiro Kono of Rice and Masayoshi Tonouchi of Osaka's Institute of Laser Engineering discovered a way to detect and identify out-of-place molecules on its surface through terahertz spectroscopy.

They expect the finding to be important to manufacturers considering the use of graphene in electronic devices.

The research was published this week by Nature's open-access online journal Scientific Reports. It was made possible by the Rice-based NanoJapan program, through which American undergraduates conduct summer research internships in Japanese labs.

Even a single molecule of a foreign substance can contaminate graphene enough to affect its electrical and optical properties, Kono said. Unfortunately (and perhaps ironically), that includes electrical contacts.

"Traditionally, in order to measure conductivity in a material, one has to attach contacts and then do electrical measurements," said Kono, whose lab specializes in terahertz research. "But our method is contact-less."

An amplitude map of terahertz radiation emitted from graphene-coated indium phosphide shows where oxygen molecules have settled on the surface after exposure to air for a few weeks. The blue at point 1 indicates high polarization due to the …more

That's possible because the compound indium phosphide emits terahertz waves when excited. The researchers used it as a substrate for graphene. Hitting the combined material with femtosecond pulses from a near-infrared laser prompted the indium phosphide to emit terahertz back through the graphene. Imperfections as small as a stray oxygen molecule on the graphene were picked up by a spectrometer.

"The change in the terahertz signal due to adsorption of molecules is remarkable," Kono said. "Not just the intensity but also the waveform of emitted terahertz radiation totally and dynamically changes in response to molecular adsorption and desorption. The next step is to explore the ultimate sensitivity of this unique technique for gas sensing."

The technique can measure both the locations of contaminating molecules and changes over time. "The laser gradually removes oxygen molecules from the graphene, changing its density, and we can see that," Kono said.

The experiment involved growing pristine graphene via chemical vapor deposition and transferring it to an indium phosphide substrate. Laser pulses generated coherent bursts of terahertz radiation through a built-in surface electric field of the indium phosphide substrate that changed due to charge transfer between the graphene and the contaminating molecules. The terahertz wave, when visualized, reflected the change.

The experimental results are a warning for electronics manufacturers. "For any future device designs using graphene, we have to take into account the influence of the surroundings," said Kono. Graphene in a vacuum or sandwiched between noncontaminating layers would probably be stable, but exposure to air would contaminate it, he said.

The Rice and Osaka labs are continuing to collaborate on a project to measure the terahertz conductivity of graphene on various substrates, he said.

 Explore further: On the edge of graphene

More information: Scientific Reports, www.nature.com/srep/2014/14081… /full/srep06046.html

Up To 30 Gbps: New Chip Enables Record-Breaking Wireless Data Transmission Speed

http://techcrunch.com/2011/11/22/up-to-30-gbps-new-chip-enables-record-breaking-wireless-data-transmission-speed/

SERKAN TOTO

It looks like we can expect faster wireless connections in the near future: Japanese electronic parts maker Rohm yesterdayannounced [JP] it has developed a chip that reached a wireless data transmission speed of 1.5 gigabits per second in experiments, the highest level ever. And according to the company, even 30Gbps will be possible in the future.

The semi conductor device uses terahertz wavesfor data transmission, has a micro antenna attached to it and is 2cm long and 1cm high (size of the module). Rohm developed the technology in cooperation with a research team at Osaka University.

According to Japanese business daily The Nikkei, Rohm expects the new chip to cost just “several hundred yen” to produce (100 Yen currently translate to US$1.30). By way of comparison: the terahertz-based wireless chips out there now cost “several million yen”, are about 20cm square and reach a top speed of just 0.1Gbps, The Nikkei says.

Rohm plans to start mass-producing the new chips in three to four years.

Terahertz waves are coming to the real world

MY NOTE: MANY OF YOU WILL FIND THE INFORMATION IN THIS TO BE VERY INTERESTING. FLAWLESS TRANSMISSION AT 300GHZ, AND SCANNING TIME OF ONE MINUTE. THE TECHNOLOGY IS REALLY IMPROVING. UNFORTUNATELY BLOGGER WON'T LET ME COPY THE IMAGES THAT GO ALONG WITH THIS ARTICLE. YOU CAN FIND THE ONLINE VERSION, IN IT'S COMPLETE FORM HERE:
http://spie.org/x42059.xml?highlight=x2414&ArticleID=x42059

Ho-Jin Song and Tadao Nagatsuma
Photonic technologies developed for conventional fiber-optic communications can be used for terahertz-wave applications such as remote sensing and wireless communications.
7 October 2010, SPIE Newsroom. DOI: 10.1117/2.1201009.003117

Terahertz (THz) waves, commonly understood to correspond to frequencies from approximately 0.1 to 10THz, interact with the vibrational resonances of many molecules. This results in absorption or radiation at specific frequencies. Therefore, THz waves have long been investigated in astronomy and spectroscopy for identification of molecules in space and to characterize the composition of matter, respectively. Several technical breakthroughs made over the last few decades now allow us to generate and detect THz waves more easily. This has triggered a search for new uses of the technology in many fields, including bioscience, security, and information and communications technology. Recent advances include reliable time-domain spectroscopy, achieved by combining a femtosecond laser and photoconductive switches, and medical imaging and nondestructive testing systems whose THz-wave signal sources are based on nonlinear optical effects or use advanced semiconductor quantum devices. However, the complex technologies and bulky equipment are not suitable for practical use, especially in outdoor sensing and wireless-communications applications.

To develop compact and reliable THz-wave applications, we are using photonic technologies, which were originally developed for fiber-optic communications. One of the key photodetectors resulting from our work is a uni-traveling-carrier photodiode. Its photocurrent is dominated by a uni-carrier (specifically electrons, which are much faster than holes), resulting in very fast photo response. This is the main difference between our new device and conventional p-i-n photodetectors, where both electrons and holes contribute equally. Since their invention in 1997, UTC-PDs have been optimized to achieve higher output power at THz-wave frequencies. Recent, advanced devices exhibit promising performance for THz-wave applications. The output power has reached almost 0.5mW at 350GHz, which is sufficient for our short-distance (up to a few tens of meters) applications, such as remote sensing and ultrahigh-capacity wireless communications at frequency ranges from 200 to 500GHz, where atmospheric attenuation is relatively low.


Using UTC-PDs, we first developed a THz-wave signal generator for remote sensing. To maintain the highest possible signal-to-noise ratio, we had to generate a monochromatic THz-wave signal with a very narrow linewidth to increase the spectral density for a given power. Our signal generator consists of a UTC-PD, arrayed-waveguide gratings, optical switches, and an optical comb-signal generator equipped with nonlinear fibers. The latter exhibits excellent coherency between modes, enabling a very narrow linewidth of the output signal of a few hertz at 300GHz. Its phase noise is as low as that of instrumental-grade microwave-signal sources. Another key feature is our system's wide frequency tunability in the range from 100GHz to 1THz, which can be tuned continuously or even randomly with kHz-order resolution, while the output frequency can be locked to other frequency references. This means that phase information can be extracted using both homo- and heterodyne detection. Using the THz-wave signal generator, we have demonstrated a simple spectroscopy system for gas identification with a Schottky-barrier-diode detector. Although the test's frequency span was not very wide because of the waveguide packaging of the emitter and detector, the nitrogen dioxide's absorption characteristics were clearly obtained within a scanning time of 1min.


We also investigated THz waves for wireless communications. Because they offer extremely wide bandwidth (more than 100 times wider than that of conventional cellular systems), data capacities of up to 100GB/s are expected.5 The frequency band in excess of 275GHz, which has not yet been allocated for specific use, is especially attractive for this purpose. When 100Gbps wireless links are finally realized, one will be able to download a Blu-ray® movie (approximately 25GB) to a memory card embedded in a smart phone in just a second without having to take the phone out of one's bag or pocket. For this communications application, photonic technologies are advantageous compared to electronic approaches because of their inherent broadband nature. Photonic technologies can generate a high-frequency carrier signal and are also able to handle extremely broadband data signals. We recently performed a preliminary data-transmission experiment, in which 12.5GbB/s data was carried on THz waves at 300GHz and transmitted over a 50cm-long distance without errors. We also used the UTC-PD as a transmitter and performed amplitude-shift-keying data modulation with a commercial optical-intensity modulator. Taking the performance margins of the transmitter and receiver (such as signal power and receiver bandwidth) into consideration, we believe that data can be transmitted at up to 20GB/s.



Photonic technologies developed for telecommunications systems can now play an important role in practical THz-wave applications, such as remote sensing and wireless communications. UTC-PDs can produce a wave at up to 1THz, and many other optical components for 1.55μm telecommunications systems enable easy implementation of a variety of functions at low cost. Once we improve the output power of our UTC-PDs, sensing over longer distances or transmission of much larger data volumes will become possible.

Ho-Jin Song
NTT Microsystem Integration Laboratories
Atsugi, Japan
Ho-Jin Song received his PhD degree in information and communication engineering from Gwangju Institute of Science and Technology (Korea) in 2005. His current research involves millimeter- and terahertz-wave technologies and their application to sensing, imaging, and wireless communications.

Tadao Nagatsuma
Graduate School of Engineering Science
University of Osaka
Osaka, Japan

,