On the switching parameter variation of metal oxide RRAM - Part II: Model corroboration and device design strategy

Shimeng Yu; Ximeng Guan; H. S.Philip Wong

doi:10.1109/TED.2012.2184544

On the switching parameter variation of metal oxide RRAM - Part II: Model corroboration and device design strategy

Shimeng Yu, Ximeng Guan, H. S.Philip Wong

Research output: Contribution to journal › Article › peer-review

192 Scopus citations

Abstract

Using the model developed in Part I of this two-part paper, the simulated dc sweep and pulse transient characteristics of a metal oxide resistive random access memory cell are corroborated with the experimental data of HfO _x memory. Key switching features such as the abrupt SET process, gradual RESET process, current fluctuation in the RESET process, and multilevel resistance state distributions are captured by the simulation. The current fluctuation in the RESET process is caused by the competition between the simultaneous oxygen vacancy recombination and generation processes. The origin of the high-resistance state variation and the tail bit problem are attributed to the variation of the tunneling gap distances and the stochastic nature of new Vo generation in the tunneling gap region, respectively. The use of the write-verify technique and a bilayer oxide structure are proposed to achieve a tighter resistance distribution.

Original language	English (US)
Article number	6155085
Pages (from-to)	1183-1188
Number of pages	6
Journal	IEEE Transactions on Electron Devices
Volume	59
Issue number	4
DOIs	https://doi.org/10.1109/TED.2012.2184544
State	Published - Apr 2012
Externally published	Yes

Keywords

Parameter fluctuation
resistive random access memory (RRAM)
resistive switching
switching uniformity
tail bit
variability

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Electrical and Electronic Engineering

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10.1109/TED.2012.2184544

Cite this

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title = "On the switching parameter variation of metal oxide RRAM - Part II: Model corroboration and device design strategy",

abstract = "Using the model developed in Part I of this two-part paper, the simulated dc sweep and pulse transient characteristics of a metal oxide resistive random access memory cell are corroborated with the experimental data of HfO x memory. Key switching features such as the abrupt SET process, gradual RESET process, current fluctuation in the RESET process, and multilevel resistance state distributions are captured by the simulation. The current fluctuation in the RESET process is caused by the competition between the simultaneous oxygen vacancy recombination and generation processes. The origin of the high-resistance state variation and the tail bit problem are attributed to the variation of the tunneling gap distances and the stochastic nature of new Vo generation in the tunneling gap region, respectively. The use of the write-verify technique and a bilayer oxide structure are proposed to achieve a tighter resistance distribution.",

keywords = "Parameter fluctuation, resistive random access memory (RRAM), resistive switching, switching uniformity, tail bit, variability",

author = "Shimeng Yu and Ximeng Guan and Wong, {H. S.Philip}",

note = "Funding Information: Manuscript received September 25, 2011; accepted January 10, 2012. Date of publication February 17, 2012; date of current version March 23, 2012. This work was supported in part by the member companies of the Stanford Nonvolatile Memory Technology Research Initiative (NMTRI), the National Science Foundation (NSF, ECCS 0950305), the Nanoelectronics Research Initiative (NRI) of the Semiconductor Research Corporation through the NSF/NRI Supplement to the NSF NSEC Center for Probing the Nanoscale (CPN), and the MSD and the C2S2 Focus Center, two of the six research centers funded under the Focus Center Research Program (FCRP), a Semiconductor Research Corporation subsidiary. The work of S. Yu was supported by the Stanford Graduate Fellowship. The review of this paper was arranged by Editor V. R. Rao.",

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PY - 2012/4

Y1 - 2012/4

N2 - Using the model developed in Part I of this two-part paper, the simulated dc sweep and pulse transient characteristics of a metal oxide resistive random access memory cell are corroborated with the experimental data of HfO x memory. Key switching features such as the abrupt SET process, gradual RESET process, current fluctuation in the RESET process, and multilevel resistance state distributions are captured by the simulation. The current fluctuation in the RESET process is caused by the competition between the simultaneous oxygen vacancy recombination and generation processes. The origin of the high-resistance state variation and the tail bit problem are attributed to the variation of the tunneling gap distances and the stochastic nature of new Vo generation in the tunneling gap region, respectively. The use of the write-verify technique and a bilayer oxide structure are proposed to achieve a tighter resistance distribution.

AB - Using the model developed in Part I of this two-part paper, the simulated dc sweep and pulse transient characteristics of a metal oxide resistive random access memory cell are corroborated with the experimental data of HfO x memory. Key switching features such as the abrupt SET process, gradual RESET process, current fluctuation in the RESET process, and multilevel resistance state distributions are captured by the simulation. The current fluctuation in the RESET process is caused by the competition between the simultaneous oxygen vacancy recombination and generation processes. The origin of the high-resistance state variation and the tail bit problem are attributed to the variation of the tunneling gap distances and the stochastic nature of new Vo generation in the tunneling gap region, respectively. The use of the write-verify technique and a bilayer oxide structure are proposed to achieve a tighter resistance distribution.

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KW - switching uniformity

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On the switching parameter variation of metal oxide RRAM - Part II: Model corroboration and device design strategy

Abstract

Keywords

ASJC Scopus subject areas

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