High-Resolution Extreme Ultraviolet Microscopy: Imaging of Artificial and Biological Specimens with Laser-Driven Ultrafast XUV Sources (Springer Theses) - Hardcover

Zürch, Michael Werner

 
9783319123875: High-Resolution Extreme Ultraviolet Microscopy: Imaging of Artificial and Biological Specimens with Laser-Driven Ultrafast XUV Sources (Springer Theses)
Hardcover
ISBN 10: 3319123874 ISBN 13: 9783319123875
Publisher: Springer, 2014

Synopsis

This thesis describes novel approaches and implementation of high-resolution microscopy in the extreme ultraviolet light regime. Using coherent ultrafast laser-generated short wavelength radiation for illuminating samples allows imaging beyond the resolution of visible-light microscopes. Michael Zürch gives a comprehensive overview of the fundamentals and techniques involved, starting from the laser-based frequency conversion scheme and its technical implementation as well as general considerations of diffraction-based imaging at nanoscopic spatial resolution. Experiments on digital in-line holography and coherent diffraction imaging of artificial and biologic specimens are demonstrated and discussed in this book. In the field of biologic imaging, a novel award-winning cell classification scheme and its first experimental application for identifying breast cancer cells are introduced. Finally, this book presents a newly developed technique of generating structured illumination by means of so-called optical vortex beams in the extreme ultraviolet regime and proposes its general usability for super-resolution imaging.

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About the Author

Michael Zürch finished his diploma thesis in 2010 on optical induced damage in nanostructures at the Friedrich-Schiller-University Jena earning him the best diploma thesis award of the faculty. During his doctorate he contributed to eight peer-reviewed journal articles, first-authoring five of them. Furthermore, he contributed to two patents and more than a dozen conference presentations, winning an award at the SPIE Medical Imaging 2014 conference for his cancer cell classification research. He finished his PhD thesis in 2014 at the Institute of Optics and Quantum Electronics at FSU Jena on the generation of coherent laser-like extreme ultraviolet light and its application to high-resolution imaging.

From the Back Cover

This book provides a comprehensive overview of the technique of frequency conversion of ultrafast lasers towards the extreme ultraviolet (XUV) regime, starting with the frequency conversion scheme and its technical implementation as well as general considerations of diffraction-based imaging at nanoscopic spatial resolutions. The last few centuries have seen continual advances in optical microscopy, driven by the demand to image ever-smaller objects. In recent years, frequency conversion of ultrafast lasers towards the extreme ultraviolet (XUV) regime has significantly enhanced the achievable resolution thanks to shorter wavelengths. The absence of high-magnification optics in the XUV regime is a major issue associated with this technique and is tackled with direct measurement and reconstruction of coherent diffraction patterns. The experimental application of this technique in terms of digital in-line holography and coherent-diffraction imaging is demonstrated on artificial and biological specimens. The book introduces a novel, award-winning cancer-cell classification scheme based on biological imaging. Finally, it presents a newly developed technique for generating structured illumination in the XUV regime and demonstrates its usability for super-resolution imaging.

"About this title" may belong to another edition of this title.

Publisher
Springer
Publication date
2014
Language
English
ISBN 10 
3319123874
ISBN 13 
9783319123875
Binding
Hardcover
Number of pages
145

Other Popular Editions of the Same Title

9783319385655: High-Resolution Extreme Ultraviolet Microscopy: Imaging of Artificial and Biological Specimens with Laser-Driven Ultrafast XUV Sources (Springer Theses)

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ISBN 10:  3319385658 ISBN 13:  9783319385655
Publisher: Springer, 2016
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