Transmission Electron Microscopy Study on the Effect of Thermal and Electrical Stimuli on Ge2Te3 Based Memristor Devices

IF 1.9 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC Frontiers in electronics Pub Date : 2022-04-26 DOI:10.3389/felec.2022.872163
Austin Shallcross, K. Mahalingam, E. Shin, G. Subramanyam, Md. Shahanur Alam, Tarek Taha, S. Ganguli, Cynthia T. Bowers, Benson Athey, A. Hilton, Anisha Roy, R. Dhall
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Abstract

Memristor devices fabricated using the chalcogenide Ge2Te3 phase change thin films in a metal-insulator-metal structure are characterized using thermal and electrical stimuli in this study. Once the thermal and electrical stimuli are applied, cross-sectional transmission electron microscopy (TEM) and X-ray energy-dispersive spectroscopy (XEDS) analyses are performed to determine structural and compositional changes in the devices. Electrical measurements on these devices showed a need for increasing compliance current between cycles to initiate switching from low resistance state (LRS) to high resistance state (HRS). The measured resistance in HRS also exhibited a steady decrease with increase in the compliance current. High resolution TEM studies on devices in HRS showed the presence of residual crystalline phase at the top-electrode/dielectric interface, which may explain the observed dependence on compliance current. XEDS study revealed diffusion related processes at dielectric-electrode interface characterized, by the separation of Ge2Te3 into Ge- and Te- enriched interfacial layers. This was also accompanied by spikes in O level at these regions. Furthermore, in-situ heating experiments on as-grown thin films revealed a deleterious effect of Ti adhesive layer, wherein the in-diffusion of Ti leads to further degradation of the dielectric layer. This experimental physics-based study shows that the large HRS/LRS ratio below the current compliance limit of 1 mA and the ability to control the HRS and LRS by varying the compliance current are attractive for memristor and neuromorphic computing applications.
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热、电刺激对Ge2Te3基忆阻器器件影响的透射电镜研究
采用金属-绝缘体-金属结构的硫系Ge2Te3相变薄膜制备了忆阻器器件,并利用热和电刺激对其进行了表征。一旦施加了热和电刺激,就会进行横断面透射电子显微镜(TEM)和x射线能量色散光谱(XEDS)分析,以确定器件的结构和成分变化。对这些设备的电气测量表明,需要增加周期之间的顺应电流,以启动从低电阻状态(LRS)切换到高电阻状态(HRS)。随着顺应电流的增大,HRS的测量电阻也呈现出稳定的下降趋势。对HRS器件的高分辨率TEM研究表明,在顶电极/介电界面存在残余晶相,这可能解释了观察到的对顺应电流的依赖。XEDS研究揭示了Ge2Te3在介电-电极界面上的扩散相关过程,其特征是Ge2Te3分离成富Ge和富Te界面层。与此同时,这些区域的O水平也出现了峰值。此外,原位加热实验揭示了Ti胶粘剂层的有害作用,其中Ti的内扩散导致介电层进一步降解。这项基于实验物理的研究表明,低于1 mA电流顺应极限的大HRS/LRS比以及通过改变顺应电流来控制HRS和LRS的能力对于记忆电阻器和神经形态计算应用具有吸引力。
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