Characterizing Defects Inside Hexagonal Boron Nitride Using Random Telegraph Signals in van der Waals 2D Transistors

Zhujun Huang; Ryong Gyu Lee; Edoardo Cuniberto; Jiyoon Song; Jeongwon Lee; Abdullah Alharbi; Kim Kisslinger; Takashi Taniguchi; Kenji Watanabe; Yong Hoon Kim; Davood Shahrjerdi

doi:10.1021/acsnano.4c06929

Characterizing Defects Inside Hexagonal Boron Nitride Using Random Telegraph Signals in van der Waals 2D Transistors

Zhujun Huang, Ryong Gyu Lee, Edoardo Cuniberto, Jiyoon Song, Jeongwon Lee, Abdullah Alharbi, Kim Kisslinger, Takashi Taniguchi, Kenji Watanabe, Yong Hoon Kim, Davood Shahrjerdi

Electrical and Computer Engineering

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

Abstract

Single-crystal hexagonal boron nitride (hBN) is used extensively in many two-dimensional electronic and quantum devices, where defects significantly impact performance. Therefore, characterizing and engineering hBN defects are crucial for advancing these technologies. Here, we examine the capture and emission dynamics of defects in hBN by utilizing low-frequency noise (LFN) spectroscopy in hBN-encapsulated and graphene-contacted MoS₂ field-effect transistors (FETs). The low disorder of this heterostructure allows the detection of random telegraph signals (RTS) in large device dimensions of 100 μm² at cryogenic temperatures. Analysis of gate bias- and temperature-dependent LFN data indicates that RTS originates from a single trap species within hBN. By performing multispace density functional theory (MS-DFT) calculations on a gated defective hBN/MoS₂ heterostructure model, we assign substitutional carbon atoms in boron sites as the atomistic origin of RTS. This study demonstrates the utility of LFN spectroscopy combined with MS-DFT analysis on a low-disorder all-vdW FET as a powerful means for characterizing the atomistic defects in single-crystal hBN.

Original language	English (US)
Pages (from-to)	28700-28711
Number of pages	12
Journal	ACS nano
Volume	18
Issue number	42
DOIs	https://doi.org/10.1021/acsnano.4c06929
State	Published - Oct 22 2024

Keywords

defect engineering
hBN dielectric
low-disorder heterostructure
low-frequency noise
nonradiative multiphonon model
random telegraph signal

ASJC Scopus subject areas

General Materials Science
General Engineering
General Physics and Astronomy

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10.1021/acsnano.4c06929

Cite this

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title = "Characterizing Defects Inside Hexagonal Boron Nitride Using Random Telegraph Signals in van der Waals 2D Transistors",

abstract = "Single-crystal hexagonal boron nitride (hBN) is used extensively in many two-dimensional electronic and quantum devices, where defects significantly impact performance. Therefore, characterizing and engineering hBN defects are crucial for advancing these technologies. Here, we examine the capture and emission dynamics of defects in hBN by utilizing low-frequency noise (LFN) spectroscopy in hBN-encapsulated and graphene-contacted MoS2 field-effect transistors (FETs). The low disorder of this heterostructure allows the detection of random telegraph signals (RTS) in large device dimensions of 100 μm2 at cryogenic temperatures. Analysis of gate bias- and temperature-dependent LFN data indicates that RTS originates from a single trap species within hBN. By performing multispace density functional theory (MS-DFT) calculations on a gated defective hBN/MoS2 heterostructure model, we assign substitutional carbon atoms in boron sites as the atomistic origin of RTS. This study demonstrates the utility of LFN spectroscopy combined with MS-DFT analysis on a low-disorder all-vdW FET as a powerful means for characterizing the atomistic defects in single-crystal hBN.",

keywords = "defect engineering, hBN dielectric, low-disorder heterostructure, low-frequency noise, nonradiative multiphonon model, random telegraph signal",

author = "Zhujun Huang and Lee, {Ryong Gyu} and Edoardo Cuniberto and Jiyoon Song and Jeongwon Lee and Abdullah Alharbi and Kim Kisslinger and Takashi Taniguchi and Kenji Watanabe and Kim, {Yong Hoon} and Davood Shahrjerdi",

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doi = "10.1021/acsnano.4c06929",

language = "English (US)",

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T1 - Characterizing Defects Inside Hexagonal Boron Nitride Using Random Telegraph Signals in van der Waals 2D Transistors

AU - Huang, Zhujun

AU - Lee, Ryong Gyu

AU - Cuniberto, Edoardo

AU - Song, Jiyoon

AU - Lee, Jeongwon

AU - Alharbi, Abdullah

AU - Kisslinger, Kim

AU - Taniguchi, Takashi

AU - Watanabe, Kenji

AU - Kim, Yong Hoon

AU - Shahrjerdi, Davood

PY - 2024/10/22

Y1 - 2024/10/22

N2 - Single-crystal hexagonal boron nitride (hBN) is used extensively in many two-dimensional electronic and quantum devices, where defects significantly impact performance. Therefore, characterizing and engineering hBN defects are crucial for advancing these technologies. Here, we examine the capture and emission dynamics of defects in hBN by utilizing low-frequency noise (LFN) spectroscopy in hBN-encapsulated and graphene-contacted MoS2 field-effect transistors (FETs). The low disorder of this heterostructure allows the detection of random telegraph signals (RTS) in large device dimensions of 100 μm2 at cryogenic temperatures. Analysis of gate bias- and temperature-dependent LFN data indicates that RTS originates from a single trap species within hBN. By performing multispace density functional theory (MS-DFT) calculations on a gated defective hBN/MoS2 heterostructure model, we assign substitutional carbon atoms in boron sites as the atomistic origin of RTS. This study demonstrates the utility of LFN spectroscopy combined with MS-DFT analysis on a low-disorder all-vdW FET as a powerful means for characterizing the atomistic defects in single-crystal hBN.

AB - Single-crystal hexagonal boron nitride (hBN) is used extensively in many two-dimensional electronic and quantum devices, where defects significantly impact performance. Therefore, characterizing and engineering hBN defects are crucial for advancing these technologies. Here, we examine the capture and emission dynamics of defects in hBN by utilizing low-frequency noise (LFN) spectroscopy in hBN-encapsulated and graphene-contacted MoS2 field-effect transistors (FETs). The low disorder of this heterostructure allows the detection of random telegraph signals (RTS) in large device dimensions of 100 μm2 at cryogenic temperatures. Analysis of gate bias- and temperature-dependent LFN data indicates that RTS originates from a single trap species within hBN. By performing multispace density functional theory (MS-DFT) calculations on a gated defective hBN/MoS2 heterostructure model, we assign substitutional carbon atoms in boron sites as the atomistic origin of RTS. This study demonstrates the utility of LFN spectroscopy combined with MS-DFT analysis on a low-disorder all-vdW FET as a powerful means for characterizing the atomistic defects in single-crystal hBN.

KW - defect engineering

KW - hBN dielectric

KW - low-disorder heterostructure

KW - low-frequency noise

KW - nonradiative multiphonon model

KW - random telegraph signal

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Characterizing Defects Inside Hexagonal Boron Nitride Using Random Telegraph Signals in van der Waals 2D Transistors

Abstract

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