Home > Press > Researchers use electron microscope to turn nanotube into tiny transistor
Professor Dmitri Golberg has lead a time that used a unique tool inserted into an electron microscope to create a transistor thats 25,000 smaller than the width of a human hair.
CREDIT QUT |
Abstract:
An international team of researchers have used a unique tool inserted into an electron microscope to create a transistor thats 25,000 times smaller than the width of a human hair.
Researchers use electron microscope to turn nanotube into tiny transistor
Brisbane, Australia | Posted on December 24th, 2021
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 Golbergs 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.
An international team of researchers have used a unique tool inserted into an electron microscope to create a transistor thats 25,000 smaller than the width of a human hair.
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 Golbergs 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.
####
For more information, please click here
Contacts:
Rod Chester
Queensland University of Technology
Office: 61-731-389-449
Copyright © Queensland University of Technology
If you have a comment, please Contact us.
Issuers of news releases, not 7th Wave, Inc. or Nanotechnology Now, are solely responsible for the accuracy of the content.
News and information
Pop-up electronic sensors could detect when individual heart cells misbehave December 24th, 2021
Templating approach stabilizes ideal material for alternative solar cells December 24th, 2021
Examining recent developments in quantum chromodynamics: A new collection looks at recent development in the field of quantum chromodynamics from a range of perspectives December 24th, 2021
Using magnets to toggle nanolasers leads to better photonics: Controlling nanolasers with magnets lays the groundwork for more robust optical signalling December 24th, 2021
Imaging
Major instrumentation initiative for research into quantum technologies: Paderborn University receives funding from German Research Foundation December 24th, 2021
UMass Lowell scientist pioneers new class of semiconductors: $1.7M NSF project aims to improve wireless communication, imaging, more December 17th, 2021
Possible Futures
Nanotube fibers stand strong — but for how long? Rice scientists calculate how carbon nanotubes and their fibers experience fatigue December 24th, 2021
Researchers uncover the mechanism of electric field detection in microscale graphene sensors December 24th, 2021
Examining recent developments in quantum chromodynamics: A new collection looks at recent development in the field of quantum chromodynamics from a range of perspectives December 24th, 2021
Chip Technology
Fabricating stable, high-mobility transistors for next-generation display technologies December 17th, 2021
UMass Lowell scientist pioneers new class of semiconductors: $1.7M NSF project aims to improve wireless communication, imaging, more December 17th, 2021
Nanotubes/Buckyballs/Fullerenes/Nanorods
Nanotube fibers stand strong — but for how long? Rice scientists calculate how carbon nanotubes and their fibers experience fatigue December 24th, 2021
Graphene nanotubes offer an efficient replacement for carbon additives in conductive electrical heating paints November 3rd, 2021
Graphene nanotubes provide a shortcut to add conductivity to powder coatings October 1st, 2021
Scientists demonstrate pathway to forerunner of nanotubes that could lead to widespread industrial fabrication September 17th, 2021
Discoveries
SUTD researchers develop ultra-scalable artificial synapse December 24th, 2021
Researchers uncover the mechanism of electric field detection in microscale graphene sensors December 24th, 2021
Major instrumentation initiative for research into quantum technologies: Paderborn University receives funding from German Research Foundation December 24th, 2021
Examining recent developments in quantum chromodynamics: A new collection looks at recent development in the field of quantum chromodynamics from a range of perspectives December 24th, 2021
Announcements
SUTD researchers develop ultra-scalable artificial synapse December 24th, 2021
Researchers uncover the mechanism of electric field detection in microscale graphene sensors December 24th, 2021
Major instrumentation initiative for research into quantum technologies: Paderborn University receives funding from German Research Foundation December 24th, 2021
Examining recent developments in quantum chromodynamics: A new collection looks at recent development in the field of quantum chromodynamics from a range of perspectives December 24th, 2021
Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters
Pop-up electronic sensors could detect when individual heart cells misbehave December 24th, 2021
Templating approach stabilizes ideal material for alternative solar cells December 24th, 2021
Nanotube fibers stand strong — but for how long? Rice scientists calculate how carbon nanotubes and their fibers experience fatigue December 24th, 2021
Using magnets to toggle nanolasers leads to better photonics: Controlling nanolasers with magnets lays the groundwork for more robust optical signalling December 24th, 2021
Tools
Major instrumentation initiative for research into quantum technologies: Paderborn University receives funding from German Research Foundation December 24th, 2021
Oxford Instruments Atomfab® system is production-qualified at a market-leading GaN power electronics device manufacturer December 17th, 2021
Development of a high-energy-resolution, LaB6 nanowire-based field emission gun: Electron source enables atomic resolution TEM observation December 10th, 2021
New microscopy method offers 3D tracking of 100 single molecules at once November 19th, 2021