I. D. Sapozhnikov scite author profile

Nano‐mechanical oscillator (NMO) based on amorphous carbon nanowhisker (CNW) with nanotraps for resonant weighting of nanoparticles in range of mass (10−14–10−15) g is presented. NMO with nanotraps is fabricated on the top of tungsten tip using focused electron beam technique. For resonant weighting the gold nanospheres are captured under the exposure of an electron beam by nanotraps locate on the top of CNW. Jump of gold nanoparticle to the nanotrap and oscillations of CNW are visualized using scanning electron microscope (SEM). The NMO amplitude‐frequency characteristics are calculated via automated numerical analysis of the sequence of SEM images obtained during the oscillations frequency sweeping. In order to calibrate the resonance mass detector based on CNW with nanotrap the gold nanosphere with diameter of (170 ± 5) nm and mass of (49.6 ± 9.2) × 10−15 g is weighed in vacuum.

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Q‐factor study of nanomechanical system “metal tip – carbon nanowhisker” at low and ambient pressure

Lukashenko

Mukhin

Вениаминов

et al. 2016

Physica Status Solidi (a)

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Nanomechanical oscillators based on amorphous carbon whiskers, localized on the top of tungsten tip were fabricated and investigated. The whiskers were grown in the scanning electron microscope chamber using focused electron beam technique. Oscillation trajectories and amplitude-frequency characteristic of the oscillator were visualized at low and ambient pressure using a scanning electron microscope and a confocal laser-scanning microscope, respectively. We experimentally show that at ambient pressure, the resonant frequency decreases significantly but the Q-factor of the oscillator unexpectedly increases with respect to experimental data acquired at low pressure. The explanation was provided taking into account the role of thin water layer absorbed on the whisker from atmosphere. The model of the coupled oscillators is considered.

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Precise mass detector based on carbon nanooscillator

Lukashenko¹,

Komissarenko²,

Mukhin³

et al. 2016

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SPM-unit combined with optical microscope objective

Sapozhnikov¹,

Горбенко²,

Felshtyn³

et al. 2019

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I. D. Sapozhnikov

Interaction of terahertz electromagnetic radiation with a probe-object system in a terahertz apertureless near-field microscope

Resonant Mass Detector Based on Carbon Nanowhiskers with Traps for Nanoobjects Weighing

Q‐factor study of nanomechanical system “metal tip – carbon nanowhisker” at low and ambient pressure

Precise mass detector based on carbon nanooscillator

SPM-unit combined with optical microscope objective

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