Investigation of multi-layered graphene/silicon Schottky junction in oxidizing atmosphere

Filiberto Ricciardella; Maria Arcangela Nigro; Riccardo Miscioscia; Maria Lucia Miglietta; Tiziana Polichetti

doi:10.1088/1361-6463/ac0d71

Investigation of multi-layered graphene/silicon Schottky junction in oxidizing atmosphere

Filiberto Ricciardella^*, Maria Arcangela Nigro, Riccardo Miscioscia, Maria Lucia Miglietta, Tiziana Polichetti

^*Corresponding author for this work

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Abstract

In this study, we investigate a Schottky junction based on solution-processed multilayered graphene (MLG). We present a rectifying device obtained with a straightforward approach, that is drop-casting a few microliters of MLG solution simultaneously onto Si, Si-SiO2 and Si-SiO2-Cr/Au surface. Monitoring the modulation of Schottky barrier height while operating in reverse bias, we study the behavior of such prepared MLG-Si/junction (MLG-Si/J) when exposed to oxidizing atmosphere, especially to nitrogen oxide (NO2). We finally compare the sensing behavior of MLG-Si/J at 1 ppm of NO2 with that of a chemiresistor-based on similarly prepared solution-processed MLG. Our study thus opens the path towards low-cost highly sensitive graphene-based heterojunctions advantageously fabricated without any complexity in the technological process.

Original language	English
Article number	375104
Number of pages	8
Journal	Journal of Physics D: Applied Physics
Volume	54
Issue number	37
DOIs	https://doi.org/10.1088/1361-6463/ac0d71
Publication status	Published - 2021

Keywords

gas-sensors
graphene
liquid phase exfoliation
NO2
Schottky barrier height
Schottky junction

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10.1088/1361-6463/ac0d71

Ricciardella_2021_J._Phys._D _Appl._Phys._54_375104Final published version, 1.31 MBLicence: CC BY

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title = "Investigation of multi-layered graphene/silicon Schottky junction in oxidizing atmosphere",

abstract = "In this study, we investigate a Schottky junction based on solution-processed multilayered graphene (MLG). We present a rectifying device obtained with a straightforward approach, that is drop-casting a few microliters of MLG solution simultaneously onto Si, Si-SiO2 and Si-SiO2-Cr/Au surface. Monitoring the modulation of Schottky barrier height while operating in reverse bias, we study the behavior of such prepared MLG-Si/junction (MLG-Si/J) when exposed to oxidizing atmosphere, especially to nitrogen oxide (NO2). We finally compare the sensing behavior of MLG-Si/J at 1 ppm of NO2 with that of a chemiresistor-based on similarly prepared solution-processed MLG. Our study thus opens the path towards low-cost highly sensitive graphene-based heterojunctions advantageously fabricated without any complexity in the technological process.",

keywords = "gas-sensors, graphene, liquid phase exfoliation, NO2, Schottky barrier height, Schottky junction",

author = "Filiberto Ricciardella and Nigro, {Maria Arcangela} and Riccardo Miscioscia and Miglietta, {Maria Lucia} and Tiziana Polichetti",

year = "2021",

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language = "English",

volume = "54",

journal = "Journal of Physics D: Applied Physics",

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AU - Ricciardella, Filiberto

AU - Nigro, Maria Arcangela

AU - Miscioscia, Riccardo

AU - Miglietta, Maria Lucia

AU - Polichetti, Tiziana

PY - 2021

Y1 - 2021

N2 - In this study, we investigate a Schottky junction based on solution-processed multilayered graphene (MLG). We present a rectifying device obtained with a straightforward approach, that is drop-casting a few microliters of MLG solution simultaneously onto Si, Si-SiO2 and Si-SiO2-Cr/Au surface. Monitoring the modulation of Schottky barrier height while operating in reverse bias, we study the behavior of such prepared MLG-Si/junction (MLG-Si/J) when exposed to oxidizing atmosphere, especially to nitrogen oxide (NO2). We finally compare the sensing behavior of MLG-Si/J at 1 ppm of NO2 with that of a chemiresistor-based on similarly prepared solution-processed MLG. Our study thus opens the path towards low-cost highly sensitive graphene-based heterojunctions advantageously fabricated without any complexity in the technological process.

AB - In this study, we investigate a Schottky junction based on solution-processed multilayered graphene (MLG). We present a rectifying device obtained with a straightforward approach, that is drop-casting a few microliters of MLG solution simultaneously onto Si, Si-SiO2 and Si-SiO2-Cr/Au surface. Monitoring the modulation of Schottky barrier height while operating in reverse bias, we study the behavior of such prepared MLG-Si/junction (MLG-Si/J) when exposed to oxidizing atmosphere, especially to nitrogen oxide (NO2). We finally compare the sensing behavior of MLG-Si/J at 1 ppm of NO2 with that of a chemiresistor-based on similarly prepared solution-processed MLG. Our study thus opens the path towards low-cost highly sensitive graphene-based heterojunctions advantageously fabricated without any complexity in the technological process.

KW - gas-sensors

KW - graphene

KW - liquid phase exfoliation

KW - NO2

KW - Schottky barrier height

KW - Schottky junction

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ER -

Investigation of multi-layered graphene/silicon Schottky junction in oxidizing atmosphere

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