Collective motion of conducting filaments in Pt/n-type TiO 2/p-type NiO/Pt stacked resistance switching memory

Kyung Min Kim; Seul Ji Song; Gun Hwan Kim; Jun Yeong Seok; Min Hwan Lee; Jung Ho Yoon; Jucheol Park; Cheol Seong Hwang

doi:10.1002/adfm.201002282

Collective motion of conducting filaments in Pt/n-type TiO ₂/p-type NiO/Pt stacked resistance switching memory

Kyung Min Kim, Seul Ji Song, Gun Hwan Kim, Jun Yeong Seok, Min Hwan Lee, Jung Ho Yoon, Jucheol Park, Cheol Seong Hwang

School of System & Semiconductor Engineering

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

Abstract

Filamentary resistance switching (RS) is one of the more obvious and useful phenomena in the family of RS mechanisms. In filamentary RS, the long reset switching time and substantially large power consumption are the critical obstacles for microelectronic applications. In this study, an innovative solution to overcome this reset problem is suggested by stacking n-type TiO ₂ and p-type NiO films. Interestingly, in this stacked structure, the region where filament rupture and rejuvenation occurs could be arbitrarily controlled to be at any location between the interface with the metal electrode and the TiO₂ / NiO interface by using an appropriate switching sequence. This collective motion behavior of conducting filaments can be practically used to reduce reset switching time from ∼100 μs to ∼150 ns, with an extremely high off/on resistance ratio of ∼ 10⁶.

Original language	English
Pages (from-to)	1587-1592
Number of pages	6
Journal	Advanced Functional Materials
Volume	21
Issue number	9
DOIs	https://doi.org/10.1002/adfm.201002282
Publication status	Published - 2011 May 10

All Science Journal Classification (ASJC) codes

Chemistry(all)
Materials Science(all)
Condensed Matter Physics

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10.1002/adfm.201002282

Cite this

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title = "Collective motion of conducting filaments in Pt/n-type TiO 2/p-type NiO/Pt stacked resistance switching memory",

abstract = "Filamentary resistance switching (RS) is one of the more obvious and useful phenomena in the family of RS mechanisms. In filamentary RS, the long reset switching time and substantially large power consumption are the critical obstacles for microelectronic applications. In this study, an innovative solution to overcome this reset problem is suggested by stacking n-type TiO 2 and p-type NiO films. Interestingly, in this stacked structure, the region where filament rupture and rejuvenation occurs could be arbitrarily controlled to be at any location between the interface with the metal electrode and the TiO2 / NiO interface by using an appropriate switching sequence. This collective motion behavior of conducting filaments can be practically used to reduce reset switching time from ∼100 μs to ∼150 ns, with an extremely high off/on resistance ratio of ∼ 106.",

author = "Kim, {Kyung Min} and Song, {Seul Ji} and Kim, {Gun Hwan} and Seok, {Jun Yeong} and Lee, {Min Hwan} and Yoon, {Jung Ho} and Jucheol Park and Hwang, {Cheol Seong}",

year = "2011",

month = may,

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doi = "10.1002/adfm.201002282",

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journal = "Advanced Functional Materials",

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T1 - Collective motion of conducting filaments in Pt/n-type TiO 2/p-type NiO/Pt stacked resistance switching memory

AU - Kim, Kyung Min

AU - Song, Seul Ji

AU - Kim, Gun Hwan

AU - Seok, Jun Yeong

AU - Lee, Min Hwan

AU - Yoon, Jung Ho

AU - Park, Jucheol

AU - Hwang, Cheol Seong

PY - 2011/5/10

Y1 - 2011/5/10

N2 - Filamentary resistance switching (RS) is one of the more obvious and useful phenomena in the family of RS mechanisms. In filamentary RS, the long reset switching time and substantially large power consumption are the critical obstacles for microelectronic applications. In this study, an innovative solution to overcome this reset problem is suggested by stacking n-type TiO 2 and p-type NiO films. Interestingly, in this stacked structure, the region where filament rupture and rejuvenation occurs could be arbitrarily controlled to be at any location between the interface with the metal electrode and the TiO2 / NiO interface by using an appropriate switching sequence. This collective motion behavior of conducting filaments can be practically used to reduce reset switching time from ∼100 μs to ∼150 ns, with an extremely high off/on resistance ratio of ∼ 106.

AB - Filamentary resistance switching (RS) is one of the more obvious and useful phenomena in the family of RS mechanisms. In filamentary RS, the long reset switching time and substantially large power consumption are the critical obstacles for microelectronic applications. In this study, an innovative solution to overcome this reset problem is suggested by stacking n-type TiO 2 and p-type NiO films. Interestingly, in this stacked structure, the region where filament rupture and rejuvenation occurs could be arbitrarily controlled to be at any location between the interface with the metal electrode and the TiO2 / NiO interface by using an appropriate switching sequence. This collective motion behavior of conducting filaments can be practically used to reduce reset switching time from ∼100 μs to ∼150 ns, with an extremely high off/on resistance ratio of ∼ 106.

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Collective motion of conducting filaments in Pt/n-type TiO ₂/p-type NiO/Pt stacked resistance switching memory

Abstract

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