Electrical Low-Frequency 1/fγ Noise Due to Surface Diffusion of Scatterers on an Ultra-low-Noise Graphene Platform

Masahiro Kamada; Antti Laitinen; Weijun Zeng; Marco Will; Jayanta Sarkar; Kirsi Tappura; Heikki Seppä; Pertti Hakonen

doi:10.1021/acs.nanolett.1c02325

Electrical Low-Frequency 1/fγ Noise Due to Surface Diffusion of Scatterers on an Ultra-low-Noise Graphene Platform

Masahiro Kamada, Antti Laitinen, Weijun Zeng, Marco Will, Jayanta Sarkar, Kirsi Tappura, Heikki Seppä, Pertti Hakonen

VTT Technical Research Centre of Finland

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

13 Citations (Scopus)

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Abstract

Low-frequency 1/f γ noise is ubiquitous, even in high-end electronic devices. Recently, it was found that adsorbed O2 molecules provide the dominant contribution to flux noise in superconducting quantum interference devices. To clarify the basic principles of such adsorbate noise, we have investigated low-frequency noise, while the mobility of surface adsorbates is varied by temperature. We measured low-frequency current noise in suspended monolayer graphene Corbino samples under the influence of adsorbed Ne atoms. Owing to the extremely small intrinsic noise of suspended graphene, we could resolve a combination of 1/f γ and Lorentzian noise induced by the presence of Ne. We find that the 1/f γ noise is caused by surface diffusion of Ne atoms and by temporary formation of few-Ne-atom clusters. Our results support the idea that clustering dynamics of defects is relevant for understanding of 1/f noise in metallic systems.

Original language	English
Pages (from-to)	7637-7643
Number of pages	7
Journal	Nano Letters
Volume	21
Issue number	18
Early online date	7 Sept 2021
DOIs	https://doi.org/10.1021/acs.nanolett.1c02325
Publication status	Published - 22 Sept 2021
MoE publication type	A1 Journal article-refereed

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10.1021/acs.nanolett.1c02325Licence: CC BY

acs.nanolett.1c02325Final published version, 3.13 MBLicence: CC BY

https://arxiv.org/abs/2106.12452

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Electrical Low-Frequency 1/fγ Noise Due to Surface Diffusion of Scatterers on an Ultra-low-Noise Graphene Platform
Kamada, M. (Creator), Laitinen, A. (Creator), Zeng, W. (Creator), Will, M. (Creator), Sarkar, J. (Creator), Kirsi, T. (Creator), Seppä, H. (Creator) & Hakonen, P. (Creator), Zenodo, 2022
DOI: 10.5281/zenodo.6386571
Dataset

Finnish Centre of Excellence in Quantum Technology
Hakonen, P., Laitinen, A., Elo, T., Kumar, M. & Suresh, K.
01/01/2018 → 31/12/2020
Project: Academy of Finland: Other research funding
BOLOSO: Ultrasensitive bolometers for security applications
Hakonen, P., Tomi, M., Kamada, M., Manninen, J., Perelshtein, M., Zeng, W., Suresh, K., Kumar, M. & Will, M.
01/01/2018 → 31/08/2022
Project: Academy of Finland: Other research funding
1/f noise
Hakonen, P., Will, M., Haque, M., Thanniyil Sebastian, A., Kamada, M., Sarkar, J. & Perelshtein, M.
01/09/2017 → 31/08/2021
Project: Academy of Finland: Other research funding

OtaNano
Anna Rissanen (Manager)
Aalto University
Facility/equipment: Facility
OtaNano – Low Temperature Laboratory
Alexander Savin (Manager)
OtaNano
Facility/equipment: Facility

Cite this

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title = "Electrical Low-Frequency 1/fγ Noise Due to Surface Diffusion of Scatterers on an Ultra-low-Noise Graphene Platform",

abstract = "Low-frequency 1/f γ noise is ubiquitous, even in high-end electronic devices. Recently, it was found that adsorbed O2 molecules provide the dominant contribution to flux noise in superconducting quantum interference devices. To clarify the basic principles of such adsorbate noise, we have investigated low-frequency noise, while the mobility of surface adsorbates is varied by temperature. We measured low-frequency current noise in suspended monolayer graphene Corbino samples under the influence of adsorbed Ne atoms. Owing to the extremely small intrinsic noise of suspended graphene, we could resolve a combination of 1/f γ and Lorentzian noise induced by the presence of Ne. We find that the 1/f γ noise is caused by surface diffusion of Ne atoms and by temporary formation of few-Ne-atom clusters. Our results support the idea that clustering dynamics of defects is relevant for understanding of 1/f noise in metallic systems.",

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AU - Will, Marco

AU - Sarkar, Jayanta

AU - Tappura, Kirsi

AU - Seppä, Heikki

AU - Hakonen, Pertti

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AB - Low-frequency 1/f γ noise is ubiquitous, even in high-end electronic devices. Recently, it was found that adsorbed O2 molecules provide the dominant contribution to flux noise in superconducting quantum interference devices. To clarify the basic principles of such adsorbate noise, we have investigated low-frequency noise, while the mobility of surface adsorbates is varied by temperature. We measured low-frequency current noise in suspended monolayer graphene Corbino samples under the influence of adsorbed Ne atoms. Owing to the extremely small intrinsic noise of suspended graphene, we could resolve a combination of 1/f γ and Lorentzian noise induced by the presence of Ne. We find that the 1/f γ noise is caused by surface diffusion of Ne atoms and by temporary formation of few-Ne-atom clusters. Our results support the idea that clustering dynamics of defects is relevant for understanding of 1/f noise in metallic systems.

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Electrical Low-Frequency 1/fγ Noise Due to Surface Diffusion of Scatterers on an Ultra-low-Noise Graphene Platform

Abstract

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Datasets

Electrical Low-Frequency 1/fγ Noise Due to Surface Diffusion of Scatterers on an Ultra-low-Noise Graphene Platform

Projects

Finnish Centre of Excellence in Quantum Technology

BOLOSO: Ultrasensitive bolometers for security applications

1/f noise

Equipment

OtaNano

OtaNano – Low Temperature Laboratory

Cite this