Measuring sliding friction at the atomic scale

Weymouth, Alfred J.; Gretz, Oliver; Riegel, Elisabeth; Giessibl, Franz J.

doi:10.35848/1347-4065/ac5e4a

Jpn. J. Appl. Phys.

2022

DOI: 10.35848/1347-4065/ac5e4a

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Measuring sliding friction at the atomic scale

Alfred J. Weymouth

Oliver Gretz

Elisabeth Riegel

et al.

Abstract: Sliding friction is a nonconservative force in which kinetic energy is dissipated via various phenomena. We used lateral force microscopy to measure the energy loss as a tip oscillates laterally above a surface with sub-Angstrom amplitudes. By terminating the tip with a single molecule, we ensure the tip ends in a single atom. We have reported that energy is dissipated as a CO molecule at the tip apex is oscillated over pairs of atoms. This is a result of the CO being bent in different directions as the tip m… Show more

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Cited by 4 publications

(1 citation statement)

References 40 publications

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“…Here, we introduce a strategy to investigate H-atoms at the sides of flat-lying molecules. We performed lateral force microscopy (LFM), in which the AFM sensor is modified so that the tip oscillates laterally above the surface ( 11 ) and is only sensitive to the lateral component of the force on the tip ( 12 – 14 ). A lateral oscillation means that the recorded frequency shift is a direct measure of the lateral forces, which have strong contrast at the terminal edges of planar molecules.…”

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confidence: 99%

Exploring in-plane interactions beside an adsorbed molecule with lateral force microscopy

Nam,

Riegel,

Hörmann

et al. 2024

Proc. Natl. Acad. Sci. U.S.A.

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Atomic force microscopy with a CO-functionalized tip can be used to directly image the internal structure of a planar molecule and to characterize chemical bonds. However, hydrogen atoms usually cannot be directly observed due to their small size. At the same time, these atoms are highly important, since they can direct on-surface chemical reactions. Measuring in-plane interactions at the sides of PTCDA (3,4,9,10-perylenetetracarboxylic dianhydride) molecules with lateral force microscopy allowed us to directly identify hydrogen atoms via their repulsive signature, which we confirmed with a model incorporating radially symmetric atomic interactions. Additional features were observed in the force data and could not be explained by H-bonding of the CO tip with the PTCDA sides. Instead, they are caused by electrostatic interaction of the large dipole of the metal apex, which we verified with density functional theory. This calculation allowed us to estimate the strength of the dipole at the metal tip apex. To further confirm that this dipole generally affects measurements on weakly polarized systems, we investigated the archetypical surface adsorbate of a single CO molecule. We determined the radially symmetric atomic interaction to be valid over a large solid angle of 5.4 sr, corresponding to 82°. We therefore find that in both the PTCDA and CO systems, the underlying interaction preventing direct observations of H-bonding and causing a collapse of the radially symmetric model is the dipole at the metal apex, which plays a significant role when approaching closer than standard imaging heights.

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mentioning

confidence: 99%

Exploring in-plane interactions beside an adsorbed molecule with lateral force microscopy

Nam,

Riegel,

Hörmann

et al. 2024

Proc. Natl. Acad. Sci. U.S.A.

Self Cite

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How scanning probe microscopy can be supported by artificial intelligence and quantum computing?

Pregowska,

Roszkiewicz,

Osial

et al. 2024

Microscopy Res & Technique

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The impact of Artificial Intelligence (AI) is rapidly expanding, revolutionizing both science and society. It is applied to practically all areas of life, science, and technology, including materials science, which continuously requires novel tools for effective materials characterization. One of the widely used techniques is scanning probe microscopy (SPM). SPM has fundamentally changed materials engineering, biology, and chemistry by providing tools for atomic‐precision surface mapping. Despite its many advantages, it also has some drawbacks, such as long scanning times or the possibility of damaging soft‐surface materials. In this paper, we focus on the potential for supporting SPM‐based measurements, with an emphasis on the application of AI‐based algorithms, especially Machine Learning‐based algorithms, as well as quantum computing (QC). It has been found that AI can be helpful in automating experimental processes in routine operations, algorithmically searching for optimal sample regions, and elucidating structure–property relationships. Thus, it contributes to increasing the efficiency and accuracy of optical nanoscopy scanning probes. Moreover, the combination of AI‐based algorithms and QC may have enormous potential to enhance the practical application of SPM. The limitations of the AI‐QC‐based approach were also discussed. Finally, we outline a research path for improving AI‐QC‐powered SPM.Research Highlights Artificial intelligence and quantum computing as support for scanning probe microscopy. The analysis indicates a research gap in the field of scanning probe microscopy. The research aims to shed light into ai‐qc‐powered scanning probe microscopy.

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On the origin and elimination of cross coupling between tunneling current and excitation in scanning probe experiments that utilize the qPlus sensor

Schelchshorn,

Stilp,

Weiss

et al. 2023

Review of Scientific Instruments

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The qPlus sensor allows for the simultaneous operation of scanning tunneling microscopy (STM) and atomic force microscopy (AFM). When operating a combined qPlus sensor STM/AFM at large tunneling currents, a hitherto unexplained tunneling current-induced cross coupling can occur, which has already been observed decades ago. Here, we study this phenomenon both theoretically and experimentally; its origin is voltage drops on the order of μV that lead to an excitation or a damping of the oscillation, depending on the sign of the current. Ideally, the voltage drops would be phase-shifted by π/2 with respect to a proper phase angle for driving and would, thus, not be a problem. However, intrinsic RC components in the current wiring lead to a phase shift that does enable drive or damping. Our theoretical model fully describes the experimental findings, and we also propose a way to prevent current-induced excitation or damping.

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Measuring sliding friction at the atomic scale

Cited by 4 publications

References 40 publications

Exploring in-plane interactions beside an adsorbed molecule with lateral force microscopy

Exploring in-plane interactions beside an adsorbed molecule with lateral force microscopy

How scanning probe microscopy can be supported by artificial intelligence and quantum computing?

On the origin and elimination of cross coupling between tunneling current and excitation in scanning probe experiments that utilize the qPlus sensor

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