Analysis of multiscale measurements of porous microstructures based on 3D optical microscopes

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Original languageEnglish
Pages (from-to)1-9
Number of pages9
JournalMeasurement
Volume83
Publication statusPublished - 27 Jan 2016

Abstract

In this article, a multiscale measurement strategy is introduced to analyze porous microstructures and the main influences on the measurement accuracy of 3D optical microscopes are investigated. The purpose is to explore the fundamental relationship between resolution, magnification and imaging in optical systems derived from using different optical lenses and their impacts on the characterization of porous microstructures. A confocal laser scanning microscope with different lenses is used for the data acquisition. Afterwards, a post-processing for data combined with image processing is carried out to analyze the geometry differences of identical pores. The results show that the numerical aperture is the primary factor causing measurement differences of the same micro object rather than the magnification of a lens and the calibrated image pixel resolution. Moreover, the assessed geometry differences strongly depend on the size or the scale of the microstructures. This phenomenon can be treated as a good verification example for the classic Abbe-theory.

Keywords

    Microscope measurement, Numerical aperture, Porous microstructures

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Analysis of multiscale measurements of porous microstructures based on 3D optical microscopes. / Zou, Yibo; Kaestner, Markus; Reithmeier, Eduard.
In: Measurement, Vol. 83, 27.01.2016, p. 1-9.

Research output: Contribution to journalArticleResearchpeer review

Zou Y, Kaestner M, Reithmeier E. Analysis of multiscale measurements of porous microstructures based on 3D optical microscopes. Measurement. 2016 Jan 27;83:1-9. doi: 10.1016/j.measurement.2016.01.020
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abstract = "In this article, a multiscale measurement strategy is introduced to analyze porous microstructures and the main influences on the measurement accuracy of 3D optical microscopes are investigated. The purpose is to explore the fundamental relationship between resolution, magnification and imaging in optical systems derived from using different optical lenses and their impacts on the characterization of porous microstructures. A confocal laser scanning microscope with different lenses is used for the data acquisition. Afterwards, a post-processing for data combined with image processing is carried out to analyze the geometry differences of identical pores. The results show that the numerical aperture is the primary factor causing measurement differences of the same micro object rather than the magnification of a lens and the calibrated image pixel resolution. Moreover, the assessed geometry differences strongly depend on the size or the scale of the microstructures. This phenomenon can be treated as a good verification example for the classic Abbe-theory.",
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author = "Yibo Zou and Markus Kaestner and Eduard Reithmeier",
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T1 - Analysis of multiscale measurements of porous microstructures based on 3D optical microscopes

AU - Zou, Yibo

AU - Kaestner, Markus

AU - Reithmeier, Eduard

N1 - Funding information: The authors would like to thank the graduate school “ Multiscale Methods of Interface Coupling ” in Leibniz University of Hannover for the financial support.

PY - 2016/1/27

Y1 - 2016/1/27

N2 - In this article, a multiscale measurement strategy is introduced to analyze porous microstructures and the main influences on the measurement accuracy of 3D optical microscopes are investigated. The purpose is to explore the fundamental relationship between resolution, magnification and imaging in optical systems derived from using different optical lenses and their impacts on the characterization of porous microstructures. A confocal laser scanning microscope with different lenses is used for the data acquisition. Afterwards, a post-processing for data combined with image processing is carried out to analyze the geometry differences of identical pores. The results show that the numerical aperture is the primary factor causing measurement differences of the same micro object rather than the magnification of a lens and the calibrated image pixel resolution. Moreover, the assessed geometry differences strongly depend on the size or the scale of the microstructures. This phenomenon can be treated as a good verification example for the classic Abbe-theory.

AB - In this article, a multiscale measurement strategy is introduced to analyze porous microstructures and the main influences on the measurement accuracy of 3D optical microscopes are investigated. The purpose is to explore the fundamental relationship between resolution, magnification and imaging in optical systems derived from using different optical lenses and their impacts on the characterization of porous microstructures. A confocal laser scanning microscope with different lenses is used for the data acquisition. Afterwards, a post-processing for data combined with image processing is carried out to analyze the geometry differences of identical pores. The results show that the numerical aperture is the primary factor causing measurement differences of the same micro object rather than the magnification of a lens and the calibrated image pixel resolution. Moreover, the assessed geometry differences strongly depend on the size or the scale of the microstructures. This phenomenon can be treated as a good verification example for the classic Abbe-theory.

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KW - Numerical aperture

KW - Porous microstructures

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