High-frequency gas effusion through nanopores in suspended graphene

I. E. Rosłoń; R. J. Dolleman; H. Licona; M. Lee; M. Šiškins; H. Lebius; L. Madauß; M. Schleberger; F. Alijani; H. S.J. van der Zant; P. G. Steeneken

doi:10.1038/s41467-020-19893-5

High-frequency gas effusion through nanopores in suspended graphene

I. E. Rosłoń^*, R. J. Dolleman, H. Licona, M. Lee, M. Šiškins, H. Lebius, L. Madauß, M. Schleberger, F. Alijani, H. S.J. van der Zant, P. G. Steeneken

^*Corresponding author for this work

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

21 Citations (Scopus)

75 Downloads (Pure)

Abstract

Porous, atomically thin graphene membranes have interesting properties for filtration and sieving applications. Here, graphene membranes are used to pump gases through nanopores using optothermal forces, enabling the study of gas flow through nanopores at frequencies above 100 kHz. At these frequencies, the motion of graphene is closely linked to the dynamic gas flow through the nanopore and can thus be used to study gas permeation at the nanoscale. By monitoring the time delay between the actuation force and the membrane mechanical motion, the permeation time-constants of various gases through pores with diameters from 10–400 nm are shown to be significantly different. Thus, a method is presented for differentiating gases based on their molecular mass and for studying gas flow mechanisms. The presented microscopic effusion-based gas sensing methodology provides a nanomechanical alternative for large-scale mass-spectrometry and optical spectrometry based gas characterisation methods.

Original language	English
Article number	6025
Number of pages	6
Journal	Nature Communications
Volume	11
Issue number	1
DOIs	https://doi.org/10.1038/s41467-020-19893-5
Publication status	Published - 2020

Access to Document

10.1038/s41467-020-19893-5

s41467-020-19893-5Final published version, 3.37 MBLicence: CC BY

Cite this

@article{f2646c5dddb845828b90fe09e1d1f430,

title = "High-frequency gas effusion through nanopores in suspended graphene",

abstract = "Porous, atomically thin graphene membranes have interesting properties for filtration and sieving applications. Here, graphene membranes are used to pump gases through nanopores using optothermal forces, enabling the study of gas flow through nanopores at frequencies above 100 kHz. At these frequencies, the motion of graphene is closely linked to the dynamic gas flow through the nanopore and can thus be used to study gas permeation at the nanoscale. By monitoring the time delay between the actuation force and the membrane mechanical motion, the permeation time-constants of various gases through pores with diameters from 10–400 nm are shown to be significantly different. Thus, a method is presented for differentiating gases based on their molecular mass and for studying gas flow mechanisms. The presented microscopic effusion-based gas sensing methodology provides a nanomechanical alternative for large-scale mass-spectrometry and optical spectrometry based gas characterisation methods.",

author = "Ros{\l}o{\'n}, {I. E.} and Dolleman, {R. J.} and H. Licona and M. Lee and M. {\v S}i{\v s}kins and H. Lebius and L. Madau{\ss} and M. Schleberger and F. Alijani and {van der Zant}, {H. S.J.} and Steeneken, {P. G.}",

year = "2020",

doi = "10.1038/s41467-020-19893-5",

language = "English",

volume = "11",

journal = "Nature Communications",

issn = "2041-1723",

publisher = "Nature",

number = "1",

}

TY - JOUR

T1 - High-frequency gas effusion through nanopores in suspended graphene

AU - Rosłoń, I. E.

AU - Dolleman, R. J.

AU - Licona, H.

AU - Lee, M.

AU - Šiškins, M.

AU - Lebius, H.

AU - Madauß, L.

AU - Schleberger, M.

AU - Alijani, F.

AU - van der Zant, H. S.J.

AU - Steeneken, P. G.

PY - 2020

Y1 - 2020

N2 - Porous, atomically thin graphene membranes have interesting properties for filtration and sieving applications. Here, graphene membranes are used to pump gases through nanopores using optothermal forces, enabling the study of gas flow through nanopores at frequencies above 100 kHz. At these frequencies, the motion of graphene is closely linked to the dynamic gas flow through the nanopore and can thus be used to study gas permeation at the nanoscale. By monitoring the time delay between the actuation force and the membrane mechanical motion, the permeation time-constants of various gases through pores with diameters from 10–400 nm are shown to be significantly different. Thus, a method is presented for differentiating gases based on their molecular mass and for studying gas flow mechanisms. The presented microscopic effusion-based gas sensing methodology provides a nanomechanical alternative for large-scale mass-spectrometry and optical spectrometry based gas characterisation methods.

AB - Porous, atomically thin graphene membranes have interesting properties for filtration and sieving applications. Here, graphene membranes are used to pump gases through nanopores using optothermal forces, enabling the study of gas flow through nanopores at frequencies above 100 kHz. At these frequencies, the motion of graphene is closely linked to the dynamic gas flow through the nanopore and can thus be used to study gas permeation at the nanoscale. By monitoring the time delay between the actuation force and the membrane mechanical motion, the permeation time-constants of various gases through pores with diameters from 10–400 nm are shown to be significantly different. Thus, a method is presented for differentiating gases based on their molecular mass and for studying gas flow mechanisms. The presented microscopic effusion-based gas sensing methodology provides a nanomechanical alternative for large-scale mass-spectrometry and optical spectrometry based gas characterisation methods.

UR - http://www.scopus.com/inward/record.url?scp=85096757973&partnerID=8YFLogxK

U2 - 10.1038/s41467-020-19893-5

DO - 10.1038/s41467-020-19893-5

M3 - Article

AN - SCOPUS:85096757973

SN - 2041-1723

VL - 11

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 6025

ER -

High-frequency gas effusion through nanopores in suspended graphene

Abstract

Access to Document

Other files and links

Fingerprint

Cite this