A graphene-coated AFM probe for durable and reproducible nanoscale electronic measurements
A graphene-coated AFM probe for durable and reproducible nanoscale electronic measurements
Conductive atomic force microscopy (cAFM) is a powerful tool for investigating electronic and thermoelectric properties at the nanoscale. However, the widespread application of cAFM is hindered by the rapid wear and unpredictable failure of metal-coated probes, leading to poor measurement reproducibility and limited probe lifetime. Here, we report a scalable fabrication method for graphene-coated cAFM probes using the Langmuir–Blodgett technique. These probes exhibit exceptional mechanical durability, including resistance to both friction-induced wear and high-current stressing, and maintain stable electrical performance over extended use. When applied to self-assembled monolayers (SAMs), the graphene-coated probes yield narrow conductance distributions, significantly improved measurement reproducibility across different probe batches, and a substantial reduction in short-circuit artifacts. The graphene coating also provides a more compliant tip-sample contact, minimizing damage to soft molecular layers. Electronic transport and thermoelectric measurements further confirm the reliability of these probes, revealing tunnelling characteristics and Seebeck coefficients consistent with established values. Our work establishes a robust and scalable platform for nanoscale electrical characterisation, overcoming a critical limitation in conventional cAFM and opening avenues for long-term, reproducible studies in molecular electronics and beyond.
2558-2565
Wang, Xintai
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Lamantia, Angelo
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Jones, Becky Penhale
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Abdelazim, Nema
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Kolosov, Oleg. V.
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Robinson, Benjamin. J.
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4 March 2026
Wang, Xintai
c78d8425-c688-46a6-a6f0-b99efbe39a55
Lamantia, Angelo
c7a952a0-a6a0-4433-ae52-b5a634a93e4d
Jones, Becky Penhale
710c19a8-3d8d-42d4-b959-6da09c1903c8
Abdelazim, Nema
2ac8bd5e-cbf1-4d9a-adcb-65dedf244b9b
Kolosov, Oleg. V.
70ebc638-40f6-4088-b758-0056bf964164
Robinson, Benjamin. J.
6b97aadf-527d-457e-9eab-d5b08bbfbda2
Wang, Xintai, Lamantia, Angelo, Jones, Becky Penhale, Abdelazim, Nema, Kolosov, Oleg. V. and Robinson, Benjamin. J.
(2026)
A graphene-coated AFM probe for durable and reproducible nanoscale electronic measurements.
Nanoscale Adv., 8 (8), .
(doi:10.1039/D5NA00924C).
Abstract
Conductive atomic force microscopy (cAFM) is a powerful tool for investigating electronic and thermoelectric properties at the nanoscale. However, the widespread application of cAFM is hindered by the rapid wear and unpredictable failure of metal-coated probes, leading to poor measurement reproducibility and limited probe lifetime. Here, we report a scalable fabrication method for graphene-coated cAFM probes using the Langmuir–Blodgett technique. These probes exhibit exceptional mechanical durability, including resistance to both friction-induced wear and high-current stressing, and maintain stable electrical performance over extended use. When applied to self-assembled monolayers (SAMs), the graphene-coated probes yield narrow conductance distributions, significantly improved measurement reproducibility across different probe batches, and a substantial reduction in short-circuit artifacts. The graphene coating also provides a more compliant tip-sample contact, minimizing damage to soft molecular layers. Electronic transport and thermoelectric measurements further confirm the reliability of these probes, revealing tunnelling characteristics and Seebeck coefficients consistent with established values. Our work establishes a robust and scalable platform for nanoscale electrical characterisation, overcoming a critical limitation in conventional cAFM and opening avenues for long-term, reproducible studies in molecular electronics and beyond.
Text
d5na00924c
- Version of Record
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Accepted/In Press date: 3 March 2026
Published date: 4 March 2026
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Publisher Copyright:
This journal is © The Royal Society of Chemistry, 2026
Identifiers
Local EPrints ID: 511685
URI: http://eprints.soton.ac.uk/id/eprint/511685
ISSN: 2040-3372
PURE UUID: c1929bf1-ad6a-4e48-bdd4-85ee95bc7e8a
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Date deposited: 27 May 2026 16:44
Last modified: 27 May 2026 16:45
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Contributors
Author:
Xintai Wang
Author:
Angelo Lamantia
Author:
Becky Penhale Jones
Author:
Nema Abdelazim
Author:
Oleg. V. Kolosov
Author:
Benjamin. J. Robinson
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