TY - JOUR
T1 - Recent progress in artificial synaptic devices : materials, processing and applications
AU - Chen, Fandi
AU - Zhou, Yingze
AU - Zhu, Yanzhe
AU - Zhu, Renbo
AU - Guan, Peiyuan
AU - Fan, Jiajun
AU - Zhou, Lu
AU - Valanoor, Nagarajan
AU - Von Wegner, Frederic
AU - Saribatir, Ed
AU - Birznieks, Ingvars
AU - Wan, Tao
AU - Chu, Dewei
PY - 2021
Y1 - 2021
N2 - Artificial synapses are memristor-based devices mimicking biological synapses, and they are used in neuromorphic computing systems that process information in a parallel, energy efficient way and store information in an analog, non-volatile form. The next generation of computing systems are anticipated to use memristive circuits, as they can overcome the shortcomings of the von Neumann computer architecture in which the levels of memory and the CPU are separated, creating a bottleneck that causes energy-loss during information transfer. Memristors are utilized to build Resistive Random Access Memory (RRAM) that allows for multi-level data storage and construction of self-correcting, autonomous learning systems that can solve complex computational tasks that have historically required super-computing hardware. Artificial synapses have received attention since HP Labs fabricated the first practical memristor device. In this review we summarize the working principles, device architectures, fabrication and processing techniques, as well as the strategies for materials selection including binary metal oxide, perovskite, polymer, and organic materials. We also discuss the applications and challenges of using artificial synapses in artificial intelligence tasks such as image recognition, tactile sensing and speech recognition.
AB - Artificial synapses are memristor-based devices mimicking biological synapses, and they are used in neuromorphic computing systems that process information in a parallel, energy efficient way and store information in an analog, non-volatile form. The next generation of computing systems are anticipated to use memristive circuits, as they can overcome the shortcomings of the von Neumann computer architecture in which the levels of memory and the CPU are separated, creating a bottleneck that causes energy-loss during information transfer. Memristors are utilized to build Resistive Random Access Memory (RRAM) that allows for multi-level data storage and construction of self-correcting, autonomous learning systems that can solve complex computational tasks that have historically required super-computing hardware. Artificial synapses have received attention since HP Labs fabricated the first practical memristor device. In this review we summarize the working principles, device architectures, fabrication and processing techniques, as well as the strategies for materials selection including binary metal oxide, perovskite, polymer, and organic materials. We also discuss the applications and challenges of using artificial synapses in artificial intelligence tasks such as image recognition, tactile sensing and speech recognition.
UR - https://hdl.handle.net/1959.7/uws:65884
U2 - 10.1039/d1tc01211h
DO - 10.1039/d1tc01211h
M3 - Article
SN - 2050-7534
SN - 2050-7526
VL - 9
SP - 8372
EP - 8394
JO - Journal of Materials Chemistry C
JF - Journal of Materials Chemistry C
IS - 27
ER -