A CD probe with a tailored cantilever for 3D-AFM measurement

Zhang, Rui; Wu, Sen; Liu, Lu; Lu, Nianhang; Fu, Xing; Gao, Sitian; Hu, Xiaodong

doi:10.1088/1361-6501/aae8f4

Cited by 12 publications

(9 citation statements)

References 25 publications

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“…AFM can be applied in materials science (morphology, electrical, magnetic and mechanical properties) (Vlassov et al, 2018; Wang et al, 2021), physics (many physical properties of materials are detected, including those in nanophysics, mesophysics and microscopic physics) (Chen & Xu, 2020; Dufrêne et al, 2021; Zhu, Tan, & Hong, 2021), chemistry (in situ detection for chemical reactions in a controlled environment, surface chemical reactions and changes at the atomic level) (Abarghani et al, 2020; Labidi et al, 2017; McDonald et al, 2020; Silbernagl et al, 2021), biology (movement and morphology of DNA, RNA, protein and cells, in situ high‐resolution liquid imaging of interactions between membranes and viruses, protein folding molecular forces, biological macromolecules, and cell surface antigens (Amarouch et al, 2018; Pi & Cai, 2019), and surface treatments for cutting DNA, microtubules, and other small fibres) (Bitler et al, 2018; Chen & Xu, 2020; Chiorcea‐Paquim et al, 2018; Hubert et al, 2019; Main et al, 2021; Schön, 2018), microelectronics (large‐scale integrated circuit detection, local electrical properties of integrated circuit (IC), storage and reading of ultrahigh density optical/magnetic information) (Yuan et al, 2017, 2020; Zhang et al, 2018), and medicine (a powerful tool for mesoscopic and nanoscopic research on biological cells, combining an inverted biological microscope, fluorescence microscope, fluorescence energy resonance transfer microscope and confocal microscope, which are widely used in medicine, pharmacology, immunology, therapy, nanoscopic research, etc.) (Chen & Xu, 2020; Silbernagl et al, 2021; Yang, 2016; Zhou et al, 2021).…”

Section: Development Of Afmmentioning

confidence: 99%

Nanoscale physical parameters of source rocks identified by atomic force microscopy: A review

et al. 2022

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The refinement of nanoscale physical parameters of source rocks has benefitted from continuous innovations in technology and methods. Traditional methods for detecting reservoir physical properties are limited by the properties of the instruments. Atomic force microscopy (AFM) provides new methods and approaches for furthering our understanding and exploring the nanoscale world. Its wide range of applications and gradually developed multiscenario application modes make it an ideal tool for the characterization of nanoscale physical properties of source rocks (coal, shale, mudstone, sandstone, etc.). We highlight the advantages of AFM in regard to performing nondestructive 3D imaging and mechanical property measurements with nanoscale resolution in any desired environment (air, vacuum, liquid). The limitations of AFM applied to source rocks are also summarized. The process has great potential in micro/nanopore characterization, surface morphology characterization, in situ micromechanical property acquisition, wettability research, and so on. The gradual development and improvement of this new model will expand new methods, bring enlightenment to basic research on unconventional oil and gas resources, and provide a scientific basis for the exploration and development of unconventional oil and gas resources.

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Section: Development Of Afmmentioning

confidence: 99%

Nanoscale physical parameters of source rocks identified by atomic force microscopy: A review

et al. 2022

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“…However, it is extremely difficult to accurately measure microstructures such as micrometer-order small holes and grooves with a high aspect ratio. Various microstructure measurement system based on different principles have been proposed [4][5][6][7][8][9][10][11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Development of a High-Function Fiber Stylus for Microstructure Measurement with Water-Repellent and Antistatic Coatings

et al. 2023

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The precise measurement of microstructures and other micron-sized materials has garnered considerable interest in recent years. We have developed a measurement system that uses an etched small diameter optical fiber as a stylus to measure microstructures with low contact force. However, when the diameter of the stylus tip is less than a few tens of micrometers, the surface forces between the measured surface and the stylus tip become larger than the gravity of the stylus tip, causing the stylus tip to stick to the measured surface. This adhesion leads to an increase in measurement time and a decrease in measurement accuracy. In this study, we fabricated a high-function stylus with water-repellent and antistatic coatings applied to the stylus tip to reduce the adhesion between the stylus tip and measured surface due to surface forces, and conducted performance evaluation tests. As a result, the average separation distance was 13.8 µm when a fluorinated resin coating with a contact angle of 105° was used, confirming that the influence of liquid bridge forces could be reduced by approximately 78%. Additionally, when static elimination experiments were conducted by scanning the charged surface at a pitch of 0.5 µm using an antistatic coating stylus with a gold on the stylus surface, the average adsorption distance was 3.6 µm, confirming that the effect of electrostatic force could be reduced by 71%.

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“…The protruding tip on the vertical cantilever enables the detection of deep grooves and re-entrant structures. Compared with the flared probe usually used for 3D topography scanning, 36 the designed OCP with a sharp tip significantly improves the accuracy of the local CPD measurement. The proposed method contains three specific modes: a bending mode for 2D horizontal surface imaging, a torsion mode for vertical sidewall imaging, and a vector tracking-based 3D scanning mode.…”

Section: ■ Introductionmentioning

confidence: 99%

Three-Dimensional Kelvin Probe Force Microscopy

Geng

Zhang

Meng

et al. 2022

ACS Appl. Mater. Interfaces

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Traditional Kelvin probe force microscopy (KPFM) is mainly limited to the characterization of two-dimensional (2D) surfaces, and in situ surface potential (SP) imaging along 3D device surfaces remains a challenge. This paper presents a multimode 3D-KPFM based on an orthogonal cantilever probe (OCP) that can achieve SP mapping of 3D micronano structures. It integrates three working modes: a bending mode for 2D horizontal surface imaging, a torsion mode for vertical sidewall imaging, and a vector tracking-based 3D scanning mode. The customized OCP has a nanoscale tip protruding from the side and underside of the cantilever, rather than the front, and the extended tip makes the proposed approach universally applicable for 3D detection from the nanometer to micrometer scale. The spatial resolution of the proposed method is analyzed by simulation, which shows it can reduce the cantilever homogenization effect. Linearity and energy resolution measurements show that the proposed method has comparable performance to traditional methods. A comparative experiment using a gold−silicon interface verifies the accuracy of the reported method in its bending and torsion modes. Further, the imaging ability of the 3D scanning mode is confirmed in the 3D characterization of a step grating. This technique is applied to the in situ characterization of a microforce sensor with microcomb structures. The experiment results show that this method can excellently achieve the 3D quantitative characterization of topography and SP, including critical dimensions and SP along a 3D device surface. This novel 3D-KPFM technique has many potential applications in the further exploration of 3D micronano devices.

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A CD probe with a tailored cantilever for 3D-AFM measurement

Cited by 12 publications

References 25 publications

Nanoscale physical parameters of source rocks identified by atomic force microscopy: A review

Nanoscale physical parameters of source rocks identified by atomic force microscopy: A review

Development of a High-Function Fiber Stylus for Microstructure Measurement with Water-Repellent and Antistatic Coatings

Three-Dimensional Kelvin Probe Force Microscopy

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