Graphene nano-electromechanical mass sensor with high resolution at room temperature

Dong Hoon Shin; Hakseong Kim; Sung Hyun Kim; Hyeonsik Cheong; Peter G. Steeneken; Chirlmin Joo; Sang Wook Lee

doi:10.1016/j.isci.2023.105958

Graphene nano-electromechanical mass sensor with high resolution at room temperature

Dong Hoon Shin, Hakseong Kim, Sung Hyun Kim, Hyeonsik Cheong, Peter G. Steeneken, Chirlmin Joo, Sang Wook Lee^*

^*Corresponding author for this work

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

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Abstract

The inherent properties of 2D materials—light mass, high out-of-plane flexibility, and large surface area—promise great potential for precise and accurate nanomechanical mass sensing, but their application is often hampered by surface contamination. Here we demonstrate a tri-layer graphene nanomechanical resonant mass sensor with sub-attogram resolution at room temperature, fabricated by a bottom-up process. We found that Joule-heating is effective in cleaning the graphene membrane surface, which results in a large improvement in the stability of the resonance frequency. We characterized the sensor by depositing Cr metal using a stencil mask and found a mass-resolution that is sufficient to weigh very small particles, like large proteins and protein complexes, with potential applications in the fields of nanobiology and medicine.

Original language	English
Article number	105958
Number of pages	13
Journal	iScience
Volume	26
Issue number	2
DOIs	https://doi.org/10.1016/j.isci.2023.105958
Publication status	Published - 2023

Keywords

Materials class
Nanomaterials
Sensor

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10.1016/j.isci.2023.105958

1-s2.0-S2589004223000354-mainFinal published version, 2.24 MBLicence: CC BY-NC-ND

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title = "Graphene nano-electromechanical mass sensor with high resolution at room temperature",

abstract = "The inherent properties of 2D materials—light mass, high out-of-plane flexibility, and large surface area—promise great potential for precise and accurate nanomechanical mass sensing, but their application is often hampered by surface contamination. Here we demonstrate a tri-layer graphene nanomechanical resonant mass sensor with sub-attogram resolution at room temperature, fabricated by a bottom-up process. We found that Joule-heating is effective in cleaning the graphene membrane surface, which results in a large improvement in the stability of the resonance frequency. We characterized the sensor by depositing Cr metal using a stencil mask and found a mass-resolution that is sufficient to weigh very small particles, like large proteins and protein complexes, with potential applications in the fields of nanobiology and medicine.",

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AU - Shin, Dong Hoon

AU - Kim, Hakseong

AU - Kim, Sung Hyun

AU - Cheong, Hyeonsik

AU - Steeneken, Peter G.

AU - Joo, Chirlmin

AU - Lee, Sang Wook

PY - 2023

Y1 - 2023

N2 - The inherent properties of 2D materials—light mass, high out-of-plane flexibility, and large surface area—promise great potential for precise and accurate nanomechanical mass sensing, but their application is often hampered by surface contamination. Here we demonstrate a tri-layer graphene nanomechanical resonant mass sensor with sub-attogram resolution at room temperature, fabricated by a bottom-up process. We found that Joule-heating is effective in cleaning the graphene membrane surface, which results in a large improvement in the stability of the resonance frequency. We characterized the sensor by depositing Cr metal using a stencil mask and found a mass-resolution that is sufficient to weigh very small particles, like large proteins and protein complexes, with potential applications in the fields of nanobiology and medicine.

AB - The inherent properties of 2D materials—light mass, high out-of-plane flexibility, and large surface area—promise great potential for precise and accurate nanomechanical mass sensing, but their application is often hampered by surface contamination. Here we demonstrate a tri-layer graphene nanomechanical resonant mass sensor with sub-attogram resolution at room temperature, fabricated by a bottom-up process. We found that Joule-heating is effective in cleaning the graphene membrane surface, which results in a large improvement in the stability of the resonance frequency. We characterized the sensor by depositing Cr metal using a stencil mask and found a mass-resolution that is sufficient to weigh very small particles, like large proteins and protein complexes, with potential applications in the fields of nanobiology and medicine.

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Graphene nano-electromechanical mass sensor with high resolution at room temperature

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