QUT and Hort Innovation have launched a $9.8 million research project to develop Cavendish and Goldfinger bananas that are resistant to Panama Tropical Race 4 (TR4), a deadly disease that is threatening global production.
The research, published in the journal Science, involves researchers from Japan, China, Russia and Australia who have worked on the project that began five years ago.
QUT Centre for Materials Science co-director Professor Dmitri Golberg, who led the research project, said the result was a “very interesting fundamental discovery” which could lead a way for the future development of tiny transistors for future generations of advanced computing devices.
“In this work, we have shown it is possible to control the electronic properties of an individual carbon nanotube,” Professor Golberg said.
The researchers created the tiny transistor by simultaneously applying a force and low voltage which heated a carbon nanotube made up of few layers until outer tube shells separate, leaving just a single-layer nanotube.
The heat and strain then changed the “chilarity” of the nanotube, meaning the pattern in which the carbon atoms joined together to form the single-atomic layer of the nanotube wall was rearranged.
The result of the new structure connecting the carbon atoms was that the nanotube was transformed into a transistor.
Professor Golberg’s team members from the National University of Science and Technology in Moscow created a theory explaining the changes in the atomic structure and properties observed in the transistor.
Lead author Dr Dai-Ming Tang, from the International Centre for Materials Nanoarchitectonics in Japan, said the research had demonstrated the ability to manipulate the molecular properties of the nanotube to fabricated nanoscale electrical device.
Dr Tang began working on the project five years ago when Professor Golberg headed up the research group at this centre.
“Semiconducting carbon nanotubes are promising for fabricating energy-efficient nanotransistors to build beyond-silicon microprocessors,” Dr Tang said.
“However, it remains a great challenge to control the chirality of individual carbon nanotubes, which uniquely determines the atomic geometry and electronic structure.
“In this work, we designed and fabricated carbon nanotube intramolecular transistors by altering the local chirality of a metallic nanotube segment by heating and mechanical strain.”
Professor Golberg said the research in demonstrating the fundamental science in creating the tiny transistor was a promising step towards building beyond-silicon microprocessors.
Transistors, which are used to switch and amplify electronic signals, are often called the “building blocks” of all electronic devices, including computers. For example, Apple says the chip which powers the future iPhones contains 15 billion transistors.
The computer industry has been focussed on developing smaller and smaller transistors for decades, but faces the limitations of silicon.
In recent years, researchers have made significant steps in developing nanotransistors, which are so small that millions of them could fit onto the head of a pin.
“Miniaturization of transistors down to nanometer scale is a great challenge of the modern semiconducting industry and nanotechnology,” Professor Golberg said.
“The present discovery, although not practical for a mass-production of tiny transistors, shows a novel fabrication principle and opens up a new horizon of using thermomechanical treatments of nanotubes for obtaining the smallest transistors with desired characteristics.”
The research article is available online.
Rod Chester, QUT Media, 07 3138 9449, email@example.com
After hours: 0407 585 901, firstname.lastname@example.org
QUT has received $1.2 million in new ARC funding and a green light to build Australia’s largest covered outdoor facility for testing equipment, robotics and materials processing techniques in realistic Moon, Mars and asteroid conditions.