Designing MoS2 channel properties for analog memory in neuromorphic applications

Kurtash, Vladislav; Thiele, Sebastian; Mathew, Sobin; Jacobs, Heiko O.; Pezoldt, Joerg

doi:10.1116/6.0001815

Cited by 3 publications

(2 citation statements)

References 18 publications

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“…[1][2][3][4] This property allows memristors to function as nonvolatile analog memory elements with a multitude of memory states, making them a promising alternative to conventional binary memories such as flash memories or dynamic random-access memories (DRAMs). [5] Memristors have also been proposed for various applications in computing, such as neuromorphic computing and in-memory computing, due to their ability to perform data-intensive operations in a highly parallel and energy-efficient manner, as demonstrated in ref. [6].…”

Section: Introductionmentioning

confidence: 99%

Energy‐Efficient Operation Conditions of MoS₂‐Based Memristors

Kurtash

Jacobs

Pezoldt

2023

Physica Status Solidi (a)

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Sufficient energy consumption for conventional information processing makes it necessary to look for new computational methods. One of the possible solutions to this problem is neuromorphic computations using memristive devices. Memristors based on molybdenum disulfide () are a promising way to provide a sizeable amount of hysteresis at low energy costs. Herein, different configurations of memristors as well as the mechanisms involved in hysteresis formation are shown. Bottom gated configuration is beneficial in terms of hysteresis area and energy efficiency. The impact of device channel dimensions on the hysteresis area and energy consumption is discussed. Different operation conditions with triangular, rectangular, sinusoidal, and sawtooth drain‐to‐source pulses are simulated, and rectangular pulses demonstrate the highest energy efficiency. The study shows the potential to realize low‐power neuromorphic systems using memristive devices.

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Section: Introductionmentioning

confidence: 99%

Energy‐Efficient Operation Conditions of MoS₂‐Based Memristors

Kurtash

Jacobs

Pezoldt

2023

Physica Status Solidi (a)

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“…MoS 2 has emerged as a prominent representative among 2D materials by subduing many intrinsic limitations of graphene (i.e., zero bandgap) . Because of its material and electronic properties, it has attracted attention in scientific applications, such as electronic, , optoelectronic, , catalytic, − biomedicine, and neuromorphic memristive applications, − and gas sensing . Moreover, due to their interesting properties like quantum confinement and thickness-dependent bandgap, i.e., changing from 1.3 for bulk (indirect bandgap) to 1.9 eV for single-layer (direct bandgap) MoS 2 , many research approaches have been developed to synthesize large-area 2D MoS 2 .…”

Section: Introductionmentioning

confidence: 99%

Formation and Characterization of Three-Dimensional Tetrahedral MoS₂ Thin Films by Chemical Vapor Deposition

Mathew

Narasimha

Reiprich

et al. 2022

Crystal Growth & Design

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A method to synthesize the three-dimensional arrangement of bulk tetrahedral MoS2 thin films by solid source chemical vapor deposition of MoO3 and S is presented. The developed synthesizing recipe uses a temperature ramping with a constant N2 gas flow in the deposition process to grow tetrahedral MoS2 thin film layers. The study analyses the time-dependent growth morphologies, and the results are combined and presented in a growth model. A combination of optical, electron, atomic force microscopy, Raman spectroscopy, and X-ray diffraction are used to study the morphological and structural features of the tetrahedral MoS2 thin layers. The grown MoS2 is c-axis oriented 2H-MoS2. Additionally, the synthesized material is further used to fabricate back-gated field-effect transistors (FETs). The fabricated FET devices on the tetrahedral MoS2 show on/off current ratios of 106 and mobility up to ∼56 cm2 V–1 s–1 with an estimated carrier concentration of 4 × 1016 cm–3 for V GS = 0 V.

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Lithium-ion-Based Resistive Devices of LiCoO₂/LiPON/Cu With Ultrathin Interlayers of Titanium Oxide for Neuromorphic Computing

Marukame

Mizushima

Nomura

et al. 2023

IEEE J. Electron Devices Soc.

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Lithium (Li)-ion materials such as LiCoO2 and (Li3PO4)-N (LiPON) are used in Li-ion all-solid-state batteries, and are now expected to be used as ion-electron hybrid materials to create a new degree of freedom in future integrated circuits. We fabricated thin-film devices on the basis of LiCoO2/LiPON/Cu and ultrathin titanium oxide (TiOx) to demonstrate their new type of resistance change mechanism and characteristics. Multi-level resistance changes promising as synaptic plasticity were obtained, and the resistance properties enable neuromorphic computing to enter a new era.

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Designing MoS2 channel properties for analog memory in neuromorphic applications

Cited by 3 publications

References 18 publications

Energy‐Efficient Operation Conditions of MoS₂‐Based Memristors

Energy‐Efficient Operation Conditions of MoS₂‐Based Memristors

Formation and Characterization of Three-Dimensional Tetrahedral MoS₂ Thin Films by Chemical Vapor Deposition

Lithium-ion-Based Resistive Devices of LiCoO₂/LiPON/Cu With Ultrathin Interlayers of Titanium Oxide for Neuromorphic Computing

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Designing MoS2 channel properties for analog memory in neuromorphic applications

Cited by 3 publications

References 18 publications

Energy‐Efficient Operation Conditions of MoS2‐Based Memristors

Energy‐Efficient Operation Conditions of MoS2‐Based Memristors

Formation and Characterization of Three-Dimensional Tetrahedral MoS2 Thin Films by Chemical Vapor Deposition

Lithium-ion-Based Resistive Devices of LiCoO2/LiPON/Cu With Ultrathin Interlayers of Titanium Oxide for Neuromorphic Computing

Contact Info

Product

Resources

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Energy‐Efficient Operation Conditions of MoS₂‐Based Memristors

Energy‐Efficient Operation Conditions of MoS₂‐Based Memristors

Formation and Characterization of Three-Dimensional Tetrahedral MoS₂ Thin Films by Chemical Vapor Deposition

Lithium-ion-Based Resistive Devices of LiCoO₂/LiPON/Cu With Ultrathin Interlayers of Titanium Oxide for Neuromorphic Computing