Resistive random-access memory with an a-Si/SiNx double-layer

Hui Tae Kwon; Won Joo Lee; Hyun Seok Choi; Daehoon Wee; Yu Jeong Park; Boram Kim; Min Hwi Kim; Sungjun Kim; Byung Gook Park; Yoon Kim

doi:10.1016/j.sse.2019.05.014

Resistive random-access memory with an a-Si/SiN_x double-layer

Hui Tae Kwon, Won Joo Lee, Hyun Seok Choi, Daehoon Wee, Yu Jeong Park, Boram Kim, Min Hwi Kim, Sungjun Kim, Byung Gook Park, Yoon Kim

Department of Electronics & Electrical Engineering

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

4 Scopus citations

Abstract

Resistive random-access memory (RRAM) with a Ni/SiN_x/a-Si/p⁺-Si structure is presented. In contrast to RRAM devices based on high-k materials, the proposed Si-based device is more attractive and promising because the SiN_x and a-Si layers have full compatibility with conventional complementary metal-oxidesemiconductor technology. The proposed device is compared to a control device with a single layer of SiN_x. A conduction path containing Si dangling bonds (traps) can be generated in both the SiN_x and a-Si layers. The conduction path in each layer can be controlled by the compliance current during the forming process. For high compliance current mode, the double-layer device has a higher ON/OFF ratio (∼10⁴) and lower leakage current (∼10^-9 A) than the single-layer device. For low compliance current mode, better non-linearity (∼10³) can be obtained when a 1/2 read bias scheme is applied to the cross-point array.

Original language	English
Pages (from-to)	64-69
Number of pages	6
Journal	Solid-State Electronics
Volume	158
DOIs	https://doi.org/10.1016/j.sse.2019.05.014
State	Published - Aug 2019

Keywords

MIS (Metal-Insulator-Semiconductor) RRAM
Resistive random-access memory (RRAM)
Silicon nitride (SiN)

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10.1016/j.sse.2019.05.014

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@article{a7d197526c124cd29b08b4b6a82dd5b7,

title = "Resistive random-access memory with an a-Si/SiNx double-layer",

abstract = "Resistive random-access memory (RRAM) with a Ni/SiNx/a-Si/p+-Si structure is presented. In contrast to RRAM devices based on high-k materials, the proposed Si-based device is more attractive and promising because the SiNx and a-Si layers have full compatibility with conventional complementary metal-oxidesemiconductor technology. The proposed device is compared to a control device with a single layer of SiNx. A conduction path containing Si dangling bonds (traps) can be generated in both the SiNx and a-Si layers. The conduction path in each layer can be controlled by the compliance current during the forming process. For high compliance current mode, the double-layer device has a higher ON/OFF ratio (∼104) and lower leakage current (∼10-9 A) than the single-layer device. For low compliance current mode, better non-linearity (∼103) can be obtained when a 1/2 read bias scheme is applied to the cross-point array.",

keywords = "MIS (Metal-Insulator-Semiconductor) RRAM, Resistive random-access memory (RRAM), Silicon nitride (SiN)",

author = "Kwon, {Hui Tae} and Lee, {Won Joo} and Choi, {Hyun Seok} and Daehoon Wee and Park, {Yu Jeong} and Boram Kim and Kim, {Min Hwi} and Sungjun Kim and Park, {Byung Gook} and Yoon Kim",

note = "Publisher Copyright: {\textcopyright} 2019",

year = "2019",

month = aug,

doi = "10.1016/j.sse.2019.05.014",

language = "English",

volume = "158",

pages = "64--69",

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T1 - Resistive random-access memory with an a-Si/SiNx double-layer

AU - Kwon, Hui Tae

AU - Lee, Won Joo

AU - Choi, Hyun Seok

AU - Wee, Daehoon

AU - Park, Yu Jeong

AU - Kim, Boram

AU - Kim, Min Hwi

AU - Kim, Sungjun

AU - Park, Byung Gook

AU - Kim, Yoon

PY - 2019/8

Y1 - 2019/8

N2 - Resistive random-access memory (RRAM) with a Ni/SiNx/a-Si/p+-Si structure is presented. In contrast to RRAM devices based on high-k materials, the proposed Si-based device is more attractive and promising because the SiNx and a-Si layers have full compatibility with conventional complementary metal-oxidesemiconductor technology. The proposed device is compared to a control device with a single layer of SiNx. A conduction path containing Si dangling bonds (traps) can be generated in both the SiNx and a-Si layers. The conduction path in each layer can be controlled by the compliance current during the forming process. For high compliance current mode, the double-layer device has a higher ON/OFF ratio (∼104) and lower leakage current (∼10-9 A) than the single-layer device. For low compliance current mode, better non-linearity (∼103) can be obtained when a 1/2 read bias scheme is applied to the cross-point array.

AB - Resistive random-access memory (RRAM) with a Ni/SiNx/a-Si/p+-Si structure is presented. In contrast to RRAM devices based on high-k materials, the proposed Si-based device is more attractive and promising because the SiNx and a-Si layers have full compatibility with conventional complementary metal-oxidesemiconductor technology. The proposed device is compared to a control device with a single layer of SiNx. A conduction path containing Si dangling bonds (traps) can be generated in both the SiNx and a-Si layers. The conduction path in each layer can be controlled by the compliance current during the forming process. For high compliance current mode, the double-layer device has a higher ON/OFF ratio (∼104) and lower leakage current (∼10-9 A) than the single-layer device. For low compliance current mode, better non-linearity (∼103) can be obtained when a 1/2 read bias scheme is applied to the cross-point array.

KW - MIS (Metal-Insulator-Semiconductor) RRAM

KW - Resistive random-access memory (RRAM)

KW - Silicon nitride (SiN)

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DO - 10.1016/j.sse.2019.05.014

M3 - Article

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SN - 0038-1101

VL - 158

SP - 64

EP - 69

JO - Solid-State Electronics

JF - Solid-State Electronics

ER -

Resistive random-access memory with an a-Si/SiN_x double-layer

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