2019
DOI: 10.1111/jmi.12792
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Multiple parametric nanoscale measurements with high sensitivity based on through‐focus scanning optical microscopy

Abstract: Summary High‐throughput through‐focus scanning optical microscopy (TSOM) involves defocusing along the optical axis and capturing a series of defocus images and is useful in optical nanoscale measurement. However, TSOM is usually affected by its optical and mechanical noises. In this study, the issue of sensitivity and application in three‐dimensional (3D) multiple parameter measurement of TSOM is investigated. First, a TSOM system with objective scanning and its relative simulation algorithm are proposed. Sec… Show more

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Cited by 5 publications
(4 citation statements)
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“…Therefore, implementing the die-to-die comparison along vertical direction rather than level direction may result in a better SNR for defect inspection. Through-focus scanning optical microscopy (TSOM) [88,89], which allows conventional optical microscopes to collect dimensional information down to the nanometer level by combining two-dimension (2D) optical images captured at several through-focus positions, has lateral and vertical measurement sensitivity of less than a nanometer [90]. As the grey area of conventional brightfield techniques used in semiconductor manufacturing is around the 11 nm node, TSOM may extend the capability of a brightfield microscope by utilizing the enriched information through z-axis slicing [91].…”
Section: Amplitude-based Optical Inspection Systemsmentioning
confidence: 99%
“…Therefore, implementing the die-to-die comparison along vertical direction rather than level direction may result in a better SNR for defect inspection. Through-focus scanning optical microscopy (TSOM) [88,89], which allows conventional optical microscopes to collect dimensional information down to the nanometer level by combining two-dimension (2D) optical images captured at several through-focus positions, has lateral and vertical measurement sensitivity of less than a nanometer [90]. As the grey area of conventional brightfield techniques used in semiconductor manufacturing is around the 11 nm node, TSOM may extend the capability of a brightfield microscope by utilizing the enriched information through z-axis slicing [91].…”
Section: Amplitude-based Optical Inspection Systemsmentioning
confidence: 99%
“…Another nondestructive optical metrology technique, through-focus scanning optical microscopy, is highly sensitive and suitable for nanostructure measurements. 93,94 The method has promising application prospects for highaspect-ratio microstructure measurements. 95,96 The measurement method extracts the size information of the structure by matching the optical simulation data library and defocused images captured along the scanning direction.…”
Section: Measurements For High-aspect-ratio Microstructuresmentioning
confidence: 99%
“…Another nondestructive optical metrology technique, through‐focus scanning optical microscopy, is highly sensitive and suitable for nanostructure measurements 93,94 . The method has promising application prospects for high‐aspect‐ratio microstructure measurements 95,96 .…”
Section: Measurements For High‐aspect‐ratio Microstructuresmentioning
confidence: 99%
“…Through-focus scanning optical microscopy (TSOM), first introduced by Attota et al in 2008, has been proven accurate and high-throughput to characterize fabricated nanostructures. Unlike conventional optical microscopy, which seeks to produce focused images with the sharpest contrast, TSOM captures a series of through-focus images with the focal plane sweeping through the sample object. These defocused images describe the evolution of light in the vicinity of the object, which is associated with the k -space distribution of the scattering light and, as predicted by the Mie theory, is sensitive to the object size.…”
Section: Introductionmentioning
confidence: 99%