Synaptic variation reduction via embedding Au nanocrystals in resistive switching layer and bottom electrode interface for CuTe/CuO/TiN-stacked synaptic deviceSynaptic variation reduction via embedding Au nanocrystals in resistive switching layer and bottom electrode interface for CuTe/CuO/TiN-stacked synaptic device
- Other Titles
- Synaptic variation reduction via embedding Au nanocrystals in resistive switching layer and bottom electrode interface for CuTe/CuO/TiN-stacked synaptic device
- Authors
- Park, Dong-Hyun; Park, Jea-Gun
- Issue Date
- Nov-2023
- Publisher
- 한국물리학회
- Keywords
- Conductive-bridge random-access-memory (CBRAM); Synaptic device; Au nanocrystals; Synaptic variation; Deep neural networks
- Citation
- Journal of the Korean Physical Society, v.83, no.12, pp 970 - 977
- Pages
- 8
- Indexed
- SCIE
SCOPUS
KCI
- Journal Title
- Journal of the Korean Physical Society
- Volume
- 83
- Number
- 12
- Start Page
- 970
- End Page
- 977
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/195772
- DOI
- 10.1007/s40042-023-00950-3
- ISSN
- 0374-4884
1976-8524
- Abstract
- Reliable artificial synaptic devices are essential for the stable and fast training of artificial neural networks (ANNs). Specifically, synaptic devices should be robust during the training and testing of ANNs to embed them in the hyper-scale synaptic cores of neuromorphic computing architectures. In this study, a highly reliable artificial synaptic device based on a CuTe/CuO/TiN-stacked conductive-bridge random-access memory cell having forming-free property was developed via embedding Au nanocrystals in the CuO resistive switching layer and TiN bottom electrode interface. Forming-free property was achieved by precisely designing the diameter of Au nanocrystals implementing the interface between the CuO resistive switching layer and TiN bottom electrode. In particular, this synaptic device exhibited multilevel current states when the compliance current level was varied. In addition, the synaptic device embedding Au nanocrystals (i.e., ~ 17.7 nm in diameter) showed a remarkable reduction of the variation in synaptic modulation. Furthermore, the test accuracy of image recognition via a deep neural network simulation was dramatically improved up to 91.95% using practical synaptic modulation data of the synaptic device embedding Au nanocrystals (i.e., ~ 17.7 nm in diameter).
- Files in This Item
-
Go to Link
- Appears in
Collections - 서울 공과대학 > 서울 융합전자공학부 > 1. Journal Articles

Items in ScholarWorks are protected by copyright, with all rights reserved, unless otherwise indicated.