Defect Engineering of BTe Ovonic Threshold Switch (OTS) With Nitrogen Doping for Improved Electrical and Reliability Performance

Jangseop Lee; Sanghyun Ban; Tae Hoon Lee; Hyunsang Hwang

doi:10.1109/LED.2023.3297992

Defect Engineering of BTe Ovonic Threshold Switch (OTS) With Nitrogen Doping for Improved Electrical and Reliability Performance

Jangseop Lee
, Sanghyun Ban
, Tae Hoon Lee
, Hyunsang Hwang

Pohang University of Science and Technology

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

14 Scopus citations

Abstract

This study investigates the effect of N-doping on the nanoscale (d = 30 nm) BTe ovonic threshold switch (OTS) device to achieve ideal selector characteristics in terms of leakage current, cycling endurance, and variation. Based on our findings, N-doping significantly improves device performance. In particular, the N-doped BTe OTS exhibits an ultra-low leakage current (Ioff @ 1/2 V th = 750 pA), low threshold voltage (V th) variation (σ < 30 mV), excellent cycling endurance (> 1011), and low Vth drift (γ = 30 mV/dec.) characteristics. From density functional theory (DFT) calculation, we found that an increase in Te-Te lifetime after the N-doping process can improve the reliability characteristics of the OTS device. This study contributes importantly to the development of high-performance OTS devices, providing a fundamental understanding of the role of N-doping in enhancing device properties.

Original language	English
Pages (from-to)	1468-1471
Number of pages	4
Journal	IEEE Electron Device Letters
Volume	44
Issue number	9
DOIs	https://doi.org/10.1109/LED.2023.3297992
State	Published - 1 Sep 2023

Keywords

Cross-point array
doping process
ovonic threshold switch (OTS)
selectors

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title = "Defect Engineering of BTe Ovonic Threshold Switch (OTS) With Nitrogen Doping for Improved Electrical and Reliability Performance",

abstract = "This study investigates the effect of N-doping on the nanoscale (d = 30 nm) BTe ovonic threshold switch (OTS) device to achieve ideal selector characteristics in terms of leakage current, cycling endurance, and variation. Based on our findings, N-doping significantly improves device performance. In particular, the N-doped BTe OTS exhibits an ultra-low leakage current (Ioff @ 1/2 V th = 750 pA), low threshold voltage (V th) variation (σ < 30 mV), excellent cycling endurance (> 1011), and low Vth drift (γ = 30 mV/dec.) characteristics. From density functional theory (DFT) calculation, we found that an increase in Te-Te lifetime after the N-doping process can improve the reliability characteristics of the OTS device. This study contributes importantly to the development of high-performance OTS devices, providing a fundamental understanding of the role of N-doping in enhancing device properties.",

keywords = "Cross-point array, doping process, ovonic threshold switch (OTS), selectors",

author = "Jangseop Lee and Sanghyun Ban and Lee, \{Tae Hoon\} and Hyunsang Hwang",

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doi = "10.1109/LED.2023.3297992",

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AU - Lee, Jangseop

AU - Ban, Sanghyun

AU - Lee, Tae Hoon

AU - Hwang, Hyunsang

PY - 2023/9/1

Y1 - 2023/9/1

N2 - This study investigates the effect of N-doping on the nanoscale (d = 30 nm) BTe ovonic threshold switch (OTS) device to achieve ideal selector characteristics in terms of leakage current, cycling endurance, and variation. Based on our findings, N-doping significantly improves device performance. In particular, the N-doped BTe OTS exhibits an ultra-low leakage current (Ioff @ 1/2 V th = 750 pA), low threshold voltage (V th) variation (σ < 30 mV), excellent cycling endurance (> 1011), and low Vth drift (γ = 30 mV/dec.) characteristics. From density functional theory (DFT) calculation, we found that an increase in Te-Te lifetime after the N-doping process can improve the reliability characteristics of the OTS device. This study contributes importantly to the development of high-performance OTS devices, providing a fundamental understanding of the role of N-doping in enhancing device properties.

AB - This study investigates the effect of N-doping on the nanoscale (d = 30 nm) BTe ovonic threshold switch (OTS) device to achieve ideal selector characteristics in terms of leakage current, cycling endurance, and variation. Based on our findings, N-doping significantly improves device performance. In particular, the N-doped BTe OTS exhibits an ultra-low leakage current (Ioff @ 1/2 V th = 750 pA), low threshold voltage (V th) variation (σ < 30 mV), excellent cycling endurance (> 1011), and low Vth drift (γ = 30 mV/dec.) characteristics. From density functional theory (DFT) calculation, we found that an increase in Te-Te lifetime after the N-doping process can improve the reliability characteristics of the OTS device. This study contributes importantly to the development of high-performance OTS devices, providing a fundamental understanding of the role of N-doping in enhancing device properties.

KW - Cross-point array

KW - doping process

KW - ovonic threshold switch (OTS)

KW - selectors

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DO - 10.1109/LED.2023.3297992

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JO - IEEE Electron Device Letters

JF - IEEE Electron Device Letters

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ER -

Defect Engineering of BTe Ovonic Threshold Switch (OTS) With Nitrogen Doping for Improved Electrical and Reliability Performance

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Keywords

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