Noncontact Friction in Electric Force Microscopy over a Conductor with Nonlocal Dielectric Response

Loring, Roger F.

doi:10.1021/acs.jpca.2c04428

J. Phys. Chem. A

2022

DOI: 10.1021/acs.jpca.2c04428

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Noncontact Friction in Electric Force Microscopy over a Conductor with Nonlocal Dielectric Response

Roger F. Loring

Abstract: Electric force microscopy, in which a charged probe moves above a surface, can measure thermally generated electric field fluctuations from the sample. Noncontact friction measurements of energy loss from the probe have been performed over insulators, semiconductors, and conductors and have been interpreted in terms of the dielectric response of the sample. Noncontact friction over metal surfaces has recently been ascribed to dielectric relaxation of adsorbed molecules, motivating the examination of the baseli… Show more

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2023

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Voltage fluctuations and probe frequency jitter in electric force microscopy of a conductor

Loring

2023

The Journal of Chemical Physics

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Electric force microscopy probes the statistics of electric field fluctuations from a sample surface, both through measurement of the noncontact friction exerted on the oscillating charged probe and by determination of the power spectrum of stochastic probe frequency fluctuations, referred to as “jitter.” Here we calculate the frequency jitter power spectrum determined over a conducting sample of finite thickness, whose response is characterized by a dielectric function that is wavevector-dependent. These calculations complement previous predictions of the coefficient of noncontact friction in an electric force microscopy measurement for the same model, and also previous predictions of the jitter power spectrum for a dielectric continuum. The inclusion both of a finite sample thickness and a wavevector-dependent dielectric response can significantly enhance the magnitude of the predicted jitter spectrum for a conductor, relative to a simpler model of an infinitely thick dielectric continuum. These calculations provide a baseline prediction of the jitter power spectrum generated by the dynamics of conduction electrons in a metal sample.

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Voltage fluctuations and probe frequency jitter in electric force microscopy of a conductor

Loring

2023

The Journal of Chemical Physics

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Noncontact Friction in Electric Force Microscopy over a Conductor with Nonlocal Dielectric Response

Cited by 1 publication

References 39 publications

Voltage fluctuations and probe frequency jitter in electric force microscopy of a conductor

Voltage fluctuations and probe frequency jitter in electric force microscopy of a conductor

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