Super-Resolution Three-Dimensional Topography Measurement Using Microsphere-Aided Broadband Light Interferometry

With the rapid development of the information era and super-precision fabrication technology, micro/nano technology has already become one of the most important modern scientific directions. To quantitatively characterize the defects, uniformity, quality and performances of micro/ nano devices, thre...

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Bibliographic Details
Published in:IEEE access 2024, Vol.12, p.183658-183664
Main Authors: Deng, Keran, Liu, Yangyi, Yang, Fan, Huang, Jian, Wen, Lianghua
Format: Article
Language:English
Subjects:
3D topography measurement
Biomedical materials
Broadband
Broadband communication
broadband interferometry
Image reconstruction
Image resolution
Imaging
Industrial areas
Interferometry
Light diffraction
Microscopy
Microspheres
Mirau interferometry
Nanoscale devices
Optical imaging
Optical interferometry
Optical microscopy
photonic nanojet
Scanning electron microscopy
Super-resolution microscopy
Superresolution
Three-dimensional displays
Topography
White light
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Summary:With the rapid development of the information era and super-precision fabrication technology, micro/nano technology has already become one of the most important modern scientific directions. To quantitatively characterize the defects, uniformity, quality and performances of micro/ nano devices, three-dimensional topography measurement plays a key role and has become increasingly 6important. In this paper, we proposed a microsphere-aided Mirau-based broadband light interferometry method to achieve super-resolution 3D topography reconstruction. We numerically and experimentally demonstrated that dielectric microspheres, which can introduce the phenomenon of photonic nanojet, could break the optical diffraction limit and achieve super-resolution microscopy under white light illumination. The subwavelength samples, which could not be detected by conventional microscopy, were clearly visualized by the proposed microsphere-aided microscopy. Furthermore, we applied the advanced Stoilov five-step phase shifting method to reconstruct the 3D topography. The experiment results demonstrated that our proposed microsphere-aided broadband light interferometry method could successfully reconstruct the 3D shape of nanoscale cylinders with the feature size of 228 nm and height of 150 nm with an error of 2%. As microsphere is a low-cost, easy-to-use, and super-resolution imaging method, it bears great potential to be widely applied in both scientific and industrial areas. We believe that our proposed super-resolution three-dimensional topography measurement using microsphere-aided broadband light interferometry will be of great interests in semiconductor, material, laser eavesdropping, extreme fabrication and biomedical applications.
ISSN:2169-3536
2169-3536
DOI:10.1109/ACCESS.2024.3470554