L. C. Kong scite author profile

L. C. Kong

3Publications

11Citation Statements Received

51Citation Statements Given

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Guangxi Normal University, University of Michigan–Ann Arbor

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Integrated electrostatically resonant scan tip for an atomic force microscope

Kong

Orr

Wise

1993

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The atomic force microscope (AFM) has become a practical tool for mapping surface features with a resolution better than 10 nm. As such, in recent years the demand from industry for the AFM has increased significantly. For the AFM to be a practical instrument, however, its operation must be user friendly and its performance must be consistent. The essential element of an AFM is a microprobe which uses a cantilever mounted with a sharp stylus as a force sensor. For reproducible measurements, it is crucial that the physical dimensions of the cantilever and its stylus be consistent. Typical dimensions of the cantilever are 100–200 μm in length, 20–50 μm in width, and 0.5–1.2 μm in thickness. Typical stylus dimensions include a height of at least 3 μm and a radius of tip curvature of less than 100 nm. Silicon micromachining techniques were applied to fabricate microprobes with built-in alternating-current excitation of the polysilicon cantilevers in our previous work. This article presents a compatible process for the formation of a fine grained polysilicon stylus on the cantilever and an optical port for fiber-optic interferometry readout. The process demonstrates the feasibility of integrating both electronic drive and sensing circuitry onto the microprobe for future use in multichannel AFM systems.

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Theoretical Study of the Effect of Probe Shape on Adhesion Force Between Probe and Substrate in Atomic Force Microscope Experiment

Yang¹,

Hu²,

Kong³

2013

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The quantitative description of adhesion force dependence on the probe shape is of importance in many scientific and industrial fields. We performed a theoretical study on the influences of the probe shape (the sphere and parabolic probe) on the adhesion force at different humidity in order to elucidate how the adhesion force varied with the probe shape in atomic force microscope manipulation experiment. We found that the combined action of the triple point and the Kelvin radius is the guiding trend of the adhesion force, and these two fundamental parameters are closely related to the probe shape. Meanwhile, the theoretical results demonstrated that the adhesion force are in a good agreement with the experiment data if the van der Waals force is take into account.

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Theoretical study of the effect of probe shape on adhesion force between probe and substrate in Atomic Force Microscope experiment

Kong

2015

jtam

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The quantitative description of adhesion force dependence on the probe shapes are of importance in many scientific and industrial fields. In order to elucidate how the adhesion force varied with the probe shape in atomic force microscope manipulation experiment, we performed a theoretical study of the influences of the probe shape (the sphere and parabolic probe) on the adhesion force at different humidity. We found that the combined action of the triple point and the Kelvin radius guiding the trend of the adhesion force, and these two fundamental parameters are closely related to the probe shape. Whilst, the theoretical results demonstrate that the adhesion force is in good agreement with the experiment data if the van der Waals force is taken into account.

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L. C. Kong

Integrated electrostatically resonant scan tip for an atomic force microscope

Theoretical Study of the Effect of Probe Shape on Adhesion Force Between Probe and Substrate in Atomic Force Microscope Experiment

Theoretical study of the effect of probe shape on adhesion force between probe and substrate in Atomic Force Microscope experiment

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