A parallel circuit model for multi-state resistive-switching random access memory

Albert B.K. Chen; Byung Joon Choi; Xiang Yang; I. Wei Chen

doi:10.1002/adfm.201102208

A parallel circuit model for multi-state resistive-switching random access memory

Albert B.K. Chen, Byung Joon Choi, Xiang Yang, I. Wei Chen

Dept. of Materials Science & Engineering

University of Pennsylvania

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

36 Scopus citations

Abstract

Large, rapidly growing literature is available on bipolar resistive-switching random access memories (RRAM) made of myriad of simple and advanced materials. Many of them exhibit similar resistance switching behavior but, until now, no unifying model can allow quantification of their voltage and time responses. Using a simple parallel circuit model, these responses of a newly discovered RRAM made of a thin-film random material are successfully analyzed. The analysis clearly reveals a large population of intermediate states with remarkably similar switching characteristics. Such modeling framework based on simple circuit constructs also appears applicable to several RRAM made of other materials. This simple approach to analyze data write/rewrite and memory retention in RRAM may aid their further understanding and development.

Original language	English
Pages (from-to)	546-554
Number of pages	9
Journal	Advanced Functional Materials
Volume	22
Issue number	3
DOIs	https://doi.org/10.1002/adfm.201102208
State	Published - 8 Feb 2012

Keywords

charge transport
data storage
electronic structures/processes/mechanisms
hybrid materials
thin films

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10.1002/adfm.201102208

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abstract = "Large, rapidly growing literature is available on bipolar resistive-switching random access memories (RRAM) made of myriad of simple and advanced materials. Many of them exhibit similar resistance switching behavior but, until now, no unifying model can allow quantification of their voltage and time responses. Using a simple parallel circuit model, these responses of a newly discovered RRAM made of a thin-film random material are successfully analyzed. The analysis clearly reveals a large population of intermediate states with remarkably similar switching characteristics. Such modeling framework based on simple circuit constructs also appears applicable to several RRAM made of other materials. This simple approach to analyze data write/rewrite and memory retention in RRAM may aid their further understanding and development.",

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N2 - Large, rapidly growing literature is available on bipolar resistive-switching random access memories (RRAM) made of myriad of simple and advanced materials. Many of them exhibit similar resistance switching behavior but, until now, no unifying model can allow quantification of their voltage and time responses. Using a simple parallel circuit model, these responses of a newly discovered RRAM made of a thin-film random material are successfully analyzed. The analysis clearly reveals a large population of intermediate states with remarkably similar switching characteristics. Such modeling framework based on simple circuit constructs also appears applicable to several RRAM made of other materials. This simple approach to analyze data write/rewrite and memory retention in RRAM may aid their further understanding and development.

AB - Large, rapidly growing literature is available on bipolar resistive-switching random access memories (RRAM) made of myriad of simple and advanced materials. Many of them exhibit similar resistance switching behavior but, until now, no unifying model can allow quantification of their voltage and time responses. Using a simple parallel circuit model, these responses of a newly discovered RRAM made of a thin-film random material are successfully analyzed. The analysis clearly reveals a large population of intermediate states with remarkably similar switching characteristics. Such modeling framework based on simple circuit constructs also appears applicable to several RRAM made of other materials. This simple approach to analyze data write/rewrite and memory retention in RRAM may aid their further understanding and development.

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A parallel circuit model for multi-state resistive-switching random access memory

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