Integration of ammonia-plasma-functionalized graphene nanodiscs as charge trapping centers for nonvolatile memory applications

Jer Chyi Wang; Kai Ping Chang; Chih Ting Lin; Ching Yuan Su; Fethullah Güneş; Mohamed Boutchich; Chang Hsiao Chen; Ching Hsiang Chen; Ching Shiun Chen; Lain Jong Li; Chao Sung Lai

doi:10.1016/j.carbon.2016.11.063

Integration of ammonia-plasma-functionalized graphene nanodiscs as charge trapping centers for nonvolatile memory applications

Jer Chyi Wang, Kai Ping Chang, Chih Ting Lin, Ching Yuan Su, Fethullah Güneş, Mohamed Boutchich, Chang Hsiao Chen, Ching Hsiang Chen, Ching Shiun Chen, Lain Jong Li, Chao Sung Lai

Graduate Institute of Energy Engineering

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

20 Scopus citations

Abstract

Graphene nanodiscs (GNDs), functionalized using NH₃ plasma, as charge trapping sites (CTSs) for non-volatile memory applications have been investigated in this study. The fabrication process relies on the patterning of Au nanoparticles (Au-NPs), whose thicknesses are tuned to adjust the GND density and size upon etching. A GND density as high as 8 × 10¹¹ cm⁻² and a diameter of approximately 20 nm are achieved. The functionalization of GNDs by NH₃ plasma creates N[sbnd]H⁺ functional groups that act as CTSs, as observed by Raman and Fourier transform infrared spectroscopy. This inherently enhances the density of CTSs in the GNDs, as a result, the memory window becomes more than 2.4 V and remains stable after 10⁴ operating cycles. The charge loss is less than 10% for a 10-year data retention testing, making this low-temperature process suitable for low-cost non-volatile memory applications on flexible substrates.

Original language	English
Pages (from-to)	318-324
Number of pages	7
Journal	Carbon
Volume	113
DOIs	https://doi.org/10.1016/j.carbon.2016.11.063
State	Published - 1 Mar 2017

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title = "Integration of ammonia-plasma-functionalized graphene nanodiscs as charge trapping centers for nonvolatile memory applications",

abstract = "Graphene nanodiscs (GNDs), functionalized using NH3 plasma, as charge trapping sites (CTSs) for non-volatile memory applications have been investigated in this study. The fabrication process relies on the patterning of Au nanoparticles (Au-NPs), whose thicknesses are tuned to adjust the GND density and size upon etching. A GND density as high as 8 × 1011 cm−2 and a diameter of approximately 20 nm are achieved. The functionalization of GNDs by NH3 plasma creates N[sbnd]H+ functional groups that act as CTSs, as observed by Raman and Fourier transform infrared spectroscopy. This inherently enhances the density of CTSs in the GNDs, as a result, the memory window becomes more than 2.4 V and remains stable after 104 operating cycles. The charge loss is less than 10% for a 10-year data retention testing, making this low-temperature process suitable for low-cost non-volatile memory applications on flexible substrates.",

author = "Wang, {Jer Chyi} and Chang, {Kai Ping} and Lin, {Chih Ting} and Su, {Ching Yuan} and Fethullah G{\"u}ne{\c s} and Mohamed Boutchich and Chen, {Chang Hsiao} and Chen, {Ching Hsiang} and Chen, {Ching Shiun} and Li, {Lain Jong} and Lai, {Chao Sung}",

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T1 - Integration of ammonia-plasma-functionalized graphene nanodiscs as charge trapping centers for nonvolatile memory applications

AU - Wang, Jer Chyi

AU - Chang, Kai Ping

AU - Lin, Chih Ting

AU - Su, Ching Yuan

AU - Güneş, Fethullah

AU - Boutchich, Mohamed

AU - Chen, Chang Hsiao

AU - Chen, Ching Hsiang

AU - Chen, Ching Shiun

AU - Li, Lain Jong

AU - Lai, Chao Sung

PY - 2017/3/1

Y1 - 2017/3/1

N2 - Graphene nanodiscs (GNDs), functionalized using NH3 plasma, as charge trapping sites (CTSs) for non-volatile memory applications have been investigated in this study. The fabrication process relies on the patterning of Au nanoparticles (Au-NPs), whose thicknesses are tuned to adjust the GND density and size upon etching. A GND density as high as 8 × 1011 cm−2 and a diameter of approximately 20 nm are achieved. The functionalization of GNDs by NH3 plasma creates N[sbnd]H+ functional groups that act as CTSs, as observed by Raman and Fourier transform infrared spectroscopy. This inherently enhances the density of CTSs in the GNDs, as a result, the memory window becomes more than 2.4 V and remains stable after 104 operating cycles. The charge loss is less than 10% for a 10-year data retention testing, making this low-temperature process suitable for low-cost non-volatile memory applications on flexible substrates.

AB - Graphene nanodiscs (GNDs), functionalized using NH3 plasma, as charge trapping sites (CTSs) for non-volatile memory applications have been investigated in this study. The fabrication process relies on the patterning of Au nanoparticles (Au-NPs), whose thicknesses are tuned to adjust the GND density and size upon etching. A GND density as high as 8 × 1011 cm−2 and a diameter of approximately 20 nm are achieved. The functionalization of GNDs by NH3 plasma creates N[sbnd]H+ functional groups that act as CTSs, as observed by Raman and Fourier transform infrared spectroscopy. This inherently enhances the density of CTSs in the GNDs, as a result, the memory window becomes more than 2.4 V and remains stable after 104 operating cycles. The charge loss is less than 10% for a 10-year data retention testing, making this low-temperature process suitable for low-cost non-volatile memory applications on flexible substrates.

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M3 - 期刊論文

AN - SCOPUS:85002050082

SN - 0008-6223

VL - 113

SP - 318

EP - 324

JO - Carbon

JF - Carbon

ER -

Integration of ammonia-plasma-functionalized graphene nanodiscs as charge trapping centers for nonvolatile memory applications

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