新型二维材料电阻器件

2022 IEEE International Conference on Manipulation, Manufacturing and Measurement on the Nanoscale (3M-NANO) Pub Date : 2022-08-08 DOI:10.1109/3M-NANO56083.2022.9941647

Yanming Liu, H. Tian

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摘要

电阻式随机存取存储器(RRAM)因其强大的突触和内存计算特性而受到广泛的研究。在这里，开发了四种新型RRAM或基于RRAM的器件结构，包括石墨烯插入RRAM，栅极可调谐RRAM, SnSe-RRAM，基于RRAM的MoS2灯丝晶体管。石墨烯插入RRAM提高了器件到器件和周期到周期的稳定性。此外，它的优化使设备更适合神经形态计算。栅极可调RRAM允许器件具有更多可调尺寸，允许更精细地调整电阻状态。SnSe-RRAM具有双层集成RRAM结构，可实现随机和灵活的电阻转换。基于rram的MoS2灯丝晶体管具有准0d接触特性，显示出创纪录的高开/关比。这些结果表明，RRAM的结构优化仍有很大的探索空间，这将导致更高的器件集成度和更多的应用。

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Novel 2D Materials-based Resistive Devices

Resistive Random Access Memory (RRAM) has been widely investigated for its great synaptic and in-memory computing characteristic. Here, four kinds of novel RRAM or RRAM-based devices' structure have been developed, including graphene inserted RRAM, gate tunable RRAM, SnSe-RRAM, RRAM-based MoS2 filament transistor. The graphene inserted RRAM improve the device-to-device and cycle-to-cycle stability. Moreover, its optimization makes devices more suitable for neuromorphic computing. The gate tunable RRAM allow devices to have more tunable dimensions, allowing finer tuning of resistive states. The SnSe-RRAM has a double-layer integrated RRAM structure, which leads to stochastic and flexible resistive converting. The RRAM-based MoS2 filament transistor has quasi-0D contact characteristic, which shows record high On/Off ratio. These results demonstrated that structural optimization of RRAM still has great room for exploration, which leads to higher device integration and more applications.

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2022 IEEE International Conference on Manipulation, Manufacturing and Measurement on the Nanoscale (3M-NANO)

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