Nanorobotic Manipulation System for 360 ^ Characterization Atomic Force Microscopy

Nanorobotic manipulation technique has been regarded as one of the most dominating approaches to upgrade the functions of microscope benefits from its complex and precise operation system. At the current stage, although atomic force microscopy (AFM) is capable of mapping specimens on a two-dimension...

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Bibliographic Details
Published in:IEEE transactions on industrial electronics (1982) 2020-04, Vol.67 (4), p.2916-2924
Main Authors: Wen, Yongbing, Lu, Haojian, Shen, Yajing, Xie, Hui
Format: Article
Language:English
Subjects:
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Atomic force microscopes
Atomic force microscopy
Biological materials
Force
Isotropic material
Mapping
micro/nano robot
Microscopes
Microscopy
Nanobioscience
Nanomaterials
nanorobotics system
Probes
Reconstruction
Surfaces
Task analysis
three-dimensional (3-D) nanomechanical mapping
Three-dimensional displays
Topography
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Summary:Nanorobotic manipulation technique has been regarded as one of the most dominating approaches to upgrade the functions of microscope benefits from its complex and precise operation system. At the current stage, although atomic force microscopy (AFM) is capable of mapping specimens on a two-dimensional/partial three dimensional (3-D) plane, a full orientation of 360° characterization still remains a challenge for AFM. Taking advantage of a nanorobotic manipulation system (NMS), 360° mapping and 3-D reconstruction of topography and nanomechanical properties are presented in this paper. Compared with recent advances of AFM mapping techniques, our proposed method is able to realize effective, large area characterization and integral results can be directly perceived through 3-D reconstruction. In this paper, a six degrees-of-freedom NMS assembled inside AFM and task specification are first proposed. Second, home positioning method for effective specimen rotation scanning is introduced. Third, 3-D reconstruction methods for the topography and nanomechanical properties of the specimen are presented. After that, 360° characterization of three different types of specimens, human hair (anisotropic biological material), trapezoidal cantilever, and conical micropipette (isotropic inorganic material) are adopted to demonstrate the feasibility and practicability of our proposed system. Finally, the 3-D reconstruction results of selected specimens are analyzed. This paper fills the blank of current AFM topography and nanomechanical characterization methodologies, which is expected to give a long-term impact in the fundamental nanomaterial research and practical micro/nano characterization.
ISSN:0278-0046
1557-9948
DOI:10.1109/TIE.2019.2910042