Enhanced analog synaptic behavior of SiNx/a-Si bilayer memristors through Ge implantation

Kim, Keon-Hee; Park, Soo‐Jin; Hu, Songtao; Song, Joong-Ho; Lim, Weoncheol; Jeong, YeonJoo; Kim, Jaewook; Lee, Jun Young; Kwak, Joon Young; Park, Jongkil; Park, Jong Keuk; Ju, Byeong Kwon; Jeong, Doo Seok; Kim, Inho

doi:10.1038/s41427-020-00261-0

Cited by 24 publications

(17 citation statements)

References 48 publications

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“…1a). To our best knowledge, the two main features of analogue devices-the linear switching performance and the large dynamic range of Ti 4.8% :a-Si device-display a clear deviation from the previously reported Ag 9,10,15,17,18,[33][34][35][36][37][38][39][40][41][42][43] -and Cu 44,45 -based analogue CBRAM (Fig. 2c).…”

Section: Cluster-type Memristor By Engineering Reduction Probabilitycontrasting

confidence: 71%

Cluster-type analogue memristor by engineering redox dynamics for high-performance neuromorphic computing

Kang

Kim

et al. 2022

Nat Commun

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Memristors, or memristive devices, have attracted tremendous interest in neuromorphic hardware implementation. However, the high electric-field dependence in conventional filamentary memristors results in either digital-like conductance updates or gradual switching only in a limited dynamic range. Here, we address the switching parameter, the reduction probability of Ag cations in the switching medium, and ultimately demonstrate a cluster-type analogue memristor. Ti nanoclusters are embedded into densified amorphous Si for the following reasons: low standard reduction potential, thermodynamic miscibility with Si, and alloy formation with Ag. These Ti clusters effectively induce the electrochemical reduction activity of Ag cations and allow linear potentiation/depression in tandem with a large conductance range (~244) and long data retention (~99% at 1 hour). Moreover, according to the reduction potentials of incorporated metals (Pt, Ta, W, and Ti), the extent of linearity improvement is selectively tuneable. Image processing simulation proves that the Ti4.8%:a-Si device can fully function with high accuracy as an ideal synaptic model.

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Section: Cluster-type Memristor By Engineering Reduction Probabilitycontrasting

confidence: 71%

Cluster-type analogue memristor by engineering redox dynamics for high-performance neuromorphic computing

Kang

Kim

et al. 2022

Nat Commun

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“…LTspice (17.0.22.0) was used to simulate the STDP learning rule by employing an OMIEC memristor as a STM fitted with a volatile memory model (VM model) and an electrochemical metallization (ECM) device as a long-term memory (LTM) fitted with a Yakopcic model. 20,[42][43][44] These two devices are connected in a series circuit to conduct a SPICE simulation for STDP curves by applying two consecutive pulses. Each pulse is composed of a short-duration pulse with a high amplitude (500 ms with 14 V for a presynaptic spike or 500 ms with 18 V for a postsynaptic spike) and a long-duration pulse with a low amplitude (200 ms and 6 V).…”

Section: Stdp Spice Simulationmentioning

confidence: 99%

“…Many research groups implemented LTP by using memristors such as Ag/Si, SiN x /a-Si, TiN/TaO x , TiO x /Al 2 O 3 , and HfO x /AlO x based devices. [19][20][21][22][23] However, a relatively small number of STP-based memristors have been developed, although their volatile characteristics can be used in spatio-temporal or reservoir computing in recurrent neural networks. 24,25 STP memristors are also potentially applicable to a synaptic memory, which comprises both long-term and short-term partitions, to improve the learning efficiency.…”

Section: Introductionmentioning

confidence: 99%

Emulating the short-term plasticity of a biological synapse with a ruthenium complex-based organic mixed ionic–electronic conductor

et al. 2022

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“…Kim et al reported improved conductance linearity and dynamic range in a Ag/SiN x /a-Si/p ++ Si-based ECM device through Ge implantation [ 36 ]. Ge implantation induces structural defects in the bulk and surface regions of the a-Si layer, which enables spatially uniform Ag migration and nanocluster formation in the upper SiN x layer, leading to enhanced synaptic behavior.…”

Section: Synaptic Devicesmentioning

confidence: 99%

“…Recently, synaptic devices based on various types of resistive switching devices have been utilized for brain-inspired computing [ 25 , 26 , 27 , 28 , 29 , 30 ]. Brain-inspired computing based on synaptic devices has achieved particular progress from ion-movement-based resistive switching mechanisms such as cation-movement-based filaments [ 31 , 32 , 33 , 34 , 35 , 36 ], anion-movement-based filaments [ 37 , 38 , 39 , 40 , 41 , 42 , 43 ], cation-movement-based ferroelectric polarization reversal [ 44 , 45 , 46 , 47 , 48 , 49 ], and ion-movement-based electrochemical electrolytes [ 50 , 51 , 52 , 53 , 54 , 55 , 56 , 57 ]. These ion-movement-based resistive switching devices can show a gradual change in conductance and nonvolatile characteristics, which have not been implemented in Mott-insulator-based resistive switching devices.…”

Section: Introductionmentioning

confidence: 99%

Ion-Movement-Based Synaptic Device for Brain-Inspired Computing

Yoon

Park

2022

Nanomaterials

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As the amount of data has grown exponentially with the advent of artificial intelligence and the Internet of Things, computing systems with high energy efficiency, high scalability, and high processing speed are urgently required. Unlike traditional digital computing, which suffers from the von Neumann bottleneck, brain-inspired computing can provide efficient, parallel, and low-power computation based on analog changes in synaptic connections between neurons. Synapse nodes in brain-inspired computing have been typically implemented with dozens of silicon transistors, which is an energy-intensive and non-scalable approach. Ion-movement-based synaptic devices for brain-inspired computing have attracted increasing attention for mimicking the performance of the biological synapse in the human brain due to their low area and low energy costs. This paper discusses the recent development of ion-movement-based synaptic devices for hardware implementation of brain-inspired computing and their principles of operation. From the perspective of the device-level requirements for brain-inspired computing, we address the advantages, challenges, and future prospects associated with different types of ion-movement-based synaptic devices.

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Enhanced analog synaptic behavior of SiNx/a-Si bilayer memristors through Ge implantation

Cited by 24 publications

References 48 publications

Cluster-type analogue memristor by engineering redox dynamics for high-performance neuromorphic computing

Cluster-type analogue memristor by engineering redox dynamics for high-performance neuromorphic computing

Emulating the short-term plasticity of a biological synapse with a ruthenium complex-based organic mixed ionic–electronic conductor

Ion-Movement-Based Synaptic Device for Brain-Inspired Computing

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