Electrostatically transparent graphene quantum-dot trap layers for efficient nonvolatile memory

Young Rae Kim; Yong Eun Jo; Yong Seon Shin; Won Tae Kang; Yeo Hyun Sung; Ui Yeon Won; Young Hee Lee; Woo Jong Yu

doi:10.1063/1.4914306

Electrostatically transparent graphene quantum-dot trap layers for efficient nonvolatile memory

Young Rae Kim
, Yong Eun Jo
, Yong Seon Shin
, Won Tae Kang
, Yeo Hyun Sung
, Ui Yeon Won
, Young Hee Lee
, Woo Jong Yu

Sungkyunkwan University

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

16 Scopus citations

Abstract

In this study, we have demonstrated nonvolatile memory devices using graphene quantum-dots (GQDs) trap layers with indium zinc oxide (IZO) semiconductor channel. The Fermi-level of GQD was effectively modulated by tunneling electrons near the Dirac point because of limited density of states and weak electrostatic screening in monolayer graphene. As a result, large gate modulation was driven in IZO channel to achieve a subthreshold swing of 5.21 V/dec (300 nm SiO₂ gate insulator), while Au quantum-dots memory shows 15.52 V/dec because of strong electrostatic screening in metal quantum-dots. Together, discrete charge traps of GQDs enable stable performance in the endurance test beyond 800 cycles of programming and erasing. Our study suggests the exciting potential of GQD trap layers to be used for a highly promising material in non-volatile memory devices.

Original language	English
Article number	103105
Journal	Applied Physics Letters
Volume	106
Issue number	10
DOIs	https://doi.org/10.1063/1.4914306
State	Published - 9 Mar 2015

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10.1063/1.4914306

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title = "Electrostatically transparent graphene quantum-dot trap layers for efficient nonvolatile memory",

abstract = "In this study, we have demonstrated nonvolatile memory devices using graphene quantum-dots (GQDs) trap layers with indium zinc oxide (IZO) semiconductor channel. The Fermi-level of GQD was effectively modulated by tunneling electrons near the Dirac point because of limited density of states and weak electrostatic screening in monolayer graphene. As a result, large gate modulation was driven in IZO channel to achieve a subthreshold swing of 5.21 V/dec (300 nm SiO2 gate insulator), while Au quantum-dots memory shows 15.52 V/dec because of strong electrostatic screening in metal quantum-dots. Together, discrete charge traps of GQDs enable stable performance in the endurance test beyond 800 cycles of programming and erasing. Our study suggests the exciting potential of GQD trap layers to be used for a highly promising material in non-volatile memory devices.",

author = "Kim, \{Young Rae\} and Jo, \{Yong Eun\} and Shin, \{Yong Seon\} and Kang, \{Won Tae\} and Sung, \{Yeo Hyun\} and Won, \{Ui Yeon\} and Lee, \{Young Hee\} and Yu, \{Woo Jong\}",

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doi = "10.1063/1.4914306",

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volume = "106",

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T1 - Electrostatically transparent graphene quantum-dot trap layers for efficient nonvolatile memory

AU - Kim, Young Rae

AU - Jo, Yong Eun

AU - Shin, Yong Seon

AU - Kang, Won Tae

AU - Sung, Yeo Hyun

AU - Won, Ui Yeon

AU - Lee, Young Hee

AU - Yu, Woo Jong

PY - 2015/3/9

Y1 - 2015/3/9

N2 - In this study, we have demonstrated nonvolatile memory devices using graphene quantum-dots (GQDs) trap layers with indium zinc oxide (IZO) semiconductor channel. The Fermi-level of GQD was effectively modulated by tunneling electrons near the Dirac point because of limited density of states and weak electrostatic screening in monolayer graphene. As a result, large gate modulation was driven in IZO channel to achieve a subthreshold swing of 5.21 V/dec (300 nm SiO2 gate insulator), while Au quantum-dots memory shows 15.52 V/dec because of strong electrostatic screening in metal quantum-dots. Together, discrete charge traps of GQDs enable stable performance in the endurance test beyond 800 cycles of programming and erasing. Our study suggests the exciting potential of GQD trap layers to be used for a highly promising material in non-volatile memory devices.

AB - In this study, we have demonstrated nonvolatile memory devices using graphene quantum-dots (GQDs) trap layers with indium zinc oxide (IZO) semiconductor channel. The Fermi-level of GQD was effectively modulated by tunneling electrons near the Dirac point because of limited density of states and weak electrostatic screening in monolayer graphene. As a result, large gate modulation was driven in IZO channel to achieve a subthreshold swing of 5.21 V/dec (300 nm SiO2 gate insulator), while Au quantum-dots memory shows 15.52 V/dec because of strong electrostatic screening in metal quantum-dots. Together, discrete charge traps of GQDs enable stable performance in the endurance test beyond 800 cycles of programming and erasing. Our study suggests the exciting potential of GQD trap layers to be used for a highly promising material in non-volatile memory devices.

UR - https://www.scopus.com/pages/publications/84924678712

U2 - 10.1063/1.4914306

DO - 10.1063/1.4914306

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VL - 106

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 10

M1 - 103105

ER -

Electrostatically transparent graphene quantum-dot trap layers for efficient nonvolatile memory

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