Home > Press > Development of dendritic-network-implementable artificial neurofiber transistors: Transistors with a fibrous architecture similar to those of neurons are capable of forming artificial neural networks. Fibrous networks can be used in smart wearable devices and robots
 |
| Schematic of biological presynaptic and postsynaptic neurons and a synapse (inset)
CREDIT Korea Institute of Science and Technology(KIST) |
Abstract:
Advances in artificial intelligence (AI)-based technologies have led to an astronomical increase in the amounts of data available for processing by computers. Existing computing methods often process data sequentially and therefore have large time and power requirements for processing massive quantities of information. Hence, a transition to a new computing paradigm is required to solve such challenging issues. Researchers are currently working towards developing energy-efficient neuromorphic computing technologies and hardware that are capable of processing massive amounts of information by mimicking the structure and mechanisms of the human brain.
Development of dendritic-network-implementable artificial neurofiber transistors: Transistors with a fibrous architecture similar to those of neurons are capable of forming artificial neural networks. Fibrous networks can be used in smart wearable devices and robots
Sejong, Korea | Posted on September 24th, 2021
The Korea Institute of Science and Technology (KIST) has reported that a research team led by Dr. Jung ah Lim and Dr. Hyunsu Ju of the Center for Opto-electronic Materials and Devices has successfully developed organic neurofiber transistors with an architecture and functions similar to those of neurons in the human brain, which can be used as a neural network. Research on devices that can function as neurons and synapses is needed so that large-scale computations can be performed in a manner similar to data processing in the human brain. Unlike previously developed devices that act as either neurons or synapses, the artificial neurofiber transistors developed at KIST can mimic the behaviors of both neurons and synapses. By connecting the transistors in arrays, one can easily create a structure similar to a neural network.
Biological neurons have fibrous branches that can receive multiple stimuli simultaneously, and signal transmissions are mediated by ion migrations stimulated by electrical signals. The KIST researchers developed the aforementioned artificial neurofibers using fibrous transistors previously developed by them in 2019. They devised memory transistors that remember the strengths of the applied electrical signals, similar to synapses, and transmit them via redox reactions between the semiconductor channels and ions within the insulators upon receiving the electrical stimuli from the neurofiber transistors. These artificialneurofibers also mimic the signal summation functionality of neurons.
The researchers created an artificial neural network system comprising 100 synapses using the artificial neurofibers and verified the stability of the device via speech recognition experiments. The proposed neural network was shown to achieve a recognition accuracy of 88.9% after training with speech data.
Dr. Jung Ah Lim and Dr. Hyunsu Ju note that “the novel artificial neurofiber device is an original technology that can be used to create large-scale, energy-efficient (~2 pJ/signal), and highly reliable artificial neural networks similar to that of the brain. Our artificial neurofiber device is flexible and may be used in AI-enabled wearable electronics made of semiconductor materials or in robotics.”
####
About National Research Council of Science & Technology
The Korea Institute of Science and Technology(KIST). Founded as the first multidisciplinary government-funded research institute in Korea, KIST established a national development strategy based on science and technology and disseminated various essential industrial technologies. Now, half a century later, KIST is elevating Korea’s status in the field of science and technology through world-leading fundamental technology R&D. Looking to the future, KIST will continue to strive to be a premier research institute, pursuing a brighter future for Korea and all of humanity.
The research was backed by the Ministry of Science and ICT and conducted as part of a institutional research program of KIST and the National Research Foundation of Koreas mid-career Researcher Program. This study has been published in the latest issue of Advanced Materials (IF : 27.34, JCR top 1.61%).
For more information, please click here
Contacts:
Young Mi Kim
National Research Council of Science & Technology
Office: 82-442-877-376
Expert Contacts
Dr. Lim, Jung Ah
Korea Institute of Science and Technology
Office: +82-2-958-5378
Kim, Dohyun (PR Department)
Korea Institute of Science and Technology
Office: +82-2-958-6344
Copyright © National Research Council of Science & 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.
Bookmark:
News and information
Brought into line: FAU physicists control the flow of electron pulses through a nanostructure channel September 24th, 2021
Nanocellulose decorated with proteins is suitable for 3D cell culturing September 24th, 2021
Researchers use breakthrough method to answer key question about electron states September 24th, 2021
Switching on a superfluid: Exotic phase transitions unlock pathways to future, superfluid-based technologies September 24th, 2021
Brain-Computer Interfaces
New brain-like computing device simulates human learning: Researchers conditioned device to learn by association, like Pavlov’s dog April 30th, 2021
Gentle probes could enable massive brain data collection: National Institutes of Health backing Rices Chong Xie to refine flexible nanoelectronics thread September 14th, 2020
First measurement of electron energy distributions, could enable sustainable energy technologies June 5th, 2020
Possible Futures
Micro-scale opto-thermo-mechanical actuation in the dry adhesive regime Peer-Reviewed Publication September 24th, 2021
MXene-GaN van der Waals metal-semiconductor junctions for high performance photodetection September 24th, 2021
Nanocellulose decorated with proteins is suitable for 3D cell culturing September 24th, 2021
Researchers use breakthrough method to answer key question about electron states September 24th, 2021
Chip Technology
Micro-scale opto-thermo-mechanical actuation in the dry adhesive regime Peer-Reviewed Publication September 24th, 2021
Brought into line: FAU physicists control the flow of electron pulses through a nanostructure channel September 24th, 2021
Switching on a superfluid: Exotic phase transitions unlock pathways to future, superfluid-based technologies September 24th, 2021
Announcements
Brought into line: FAU physicists control the flow of electron pulses through a nanostructure channel September 24th, 2021
Nanocellulose decorated with proteins is suitable for 3D cell culturing September 24th, 2021
Researchers use breakthrough method to answer key question about electron states September 24th, 2021
Switching on a superfluid: Exotic phase transitions unlock pathways to future, superfluid-based technologies September 24th, 2021
Interviews/Book Reviews/Essays/Reports/Podcasts/Journals/White papers/Posters
Micro-scale opto-thermo-mechanical actuation in the dry adhesive regime Peer-Reviewed Publication September 24th, 2021
MXene-GaN van der Waals metal-semiconductor junctions for high performance photodetection September 24th, 2021
Brought into line: FAU physicists control the flow of electron pulses through a nanostructure channel September 24th, 2021
Artificial Intelligence
Argonne researchers use AI to optimize a popular material coating technique in real time June 25th, 2021
Graphene key for novel hardware security May 10th, 2021
With new optical device, engineers can fine tune the color of light April 23rd, 2021
New study investigates photonics for artificial intelligence and neuromorphic computing February 1st, 2021
