This book presents the advances in super-resolution microscopy in physics and biomedical optics for nanoscale imaging. In the last decade, super-resolved fluorescence imaging has opened new horizons in improving the resolution of optical microscopes far beyond the classical diffraction limit, leading to the Nobel Prize in Chemistry in 2014. This book represents the first comprehensive review of a different type of super-resolved microscopy, which does not rely on using fluorescent markers. Such label-free super-resolution microscopy enables potentially even broader applications in life sciences and nanoscale imaging, but is much more challenging and it is based on different physical concepts and approaches. A unique feature of this book is that it combines insights into mechanisms of label-free super-resolution with a vast range of applications from fast imaging of living cells to inorganic nanostructures. This book can be used by researchers in biological and medical physics. Due to its logically organizational structure, it can be also used as a teaching tool in graduate and upper-division undergraduate-level courses devoted to super-resolved microscopy, nanoscale imaging, microscopy instrumentation, and biomedical imaging.
Recenzijas
A thorough and cutting-edge reference of the modern advances in microscopy, the book is valuable reading for researchers and physicists. (Silvano Donati, Optics & Photonics News, March 19, 2020)
1. Introduction (Vasily Astratov).-
2. Optical Resolution, Field
Entropy, and Heisenberg's Uncertainty Relation (Gabriel Popescu).-
3.
Interferometric Scattering Microscopy (iSCAT) and Related Techniques (Vahid
Sandoghdar).-
4. Label-Free, Ultrahigh-Speed Direct Imaging of
Bio-Nanoparticles in Live Cells by Coherent Brightfield (COBRI) Microscopy
(Chia-Lung Hsieh.-
5. Super-Resolution Imaging in Raman Microscopy (Katsumasa
Fujita).-
6. Toward Label-Free Superresolution Microscopy (Renee Frontiera).-
7. Label-Free Time Multiplexing Based Nanoscopy (Zeev Zalevsky).-
8. Beating
the Diffraction Limit in IR Microscopy Through Detecting the Thermal Effect
(Ji-Xin Cheng).-
9. Superresolution Imaging Based on Nonlinear Scattering
(Shi-Wei Chu).- 10. Label Free Superresolution by Nonlinear Photo-Modulated
Reflectivity (Ori Cheshnovsky) .-
11. Hyper-Structured Illumination:
Label-Free Super-Resolution Imaging with Hypebolic Metamaterials (Evgenii
Narimanov).-
12. Superresolution MicroscopyTechniques Based on Plasmonics and
Transformation Optics (. Igor Smolyaninov and Vera Smolyaninova).-
13.
Superlensing Particle Lenses for White-Light Super-Resolution Imaging (Zengbo
Wang and Boris Luk'yanchuk).-
14. Theoretical Foundations of Superresolution
in Microspherical Nanoscopy (Alexey Maslov and Vasily Astratov).-
15. Role of
Plasmonics in Super-Resolution Imaging Through Microspheres (Vasily
Astratovs group at UNC-Charlotte).-
16. Plasmonics Meets Far-Field Optical
Nanoscopy (Fernando Stefani (to be confirmed)).-
17. Superoscillatory
Focusing Technologies and Quantum Superoscillation (Nikolay Zheludev and
Edward Rogers (to be confirmed)).-
18. Perfect Imaging via Transformation
Optics (Ulf Leonhardt (to be confirmed)).-
19. Focusing and Imaging from the
Far Field Using Time Reversal in Subwavelength Scaled Resonant Media (Fabrice
Lemoult & Geoffroy Lerosey (to be confirmed)).
Vasily N. Astratov has been professor of Physics and Optical Science at the University of North Carolina-Charlotte since 2002. In 1986, he received his Ph.D. degree from the A.F. Ioffe Physical-Technical Institute in Russia. Since joining UNC-Charlotte in 2002, his research has been devoted to a new field of study which he has named "microspherical photonics" to describe the applications of dielectric microspheres in super-resolution microscopy, resonant light forces, photonic nanojets, and photonic molecules. In his lab, he proposed and developed the methods of super-resolution imaging based on using high-index dielectric microspheres immersed in liquids or in elastomeric slabs. His methods are widely used by many groups worldwide for imaging subcellular structures, viruses, and nanoplasmonic structures. He also observed giant light forces exerted on microspheres under resonant conditions with their whispering gallery modes. This observation builds upon earlier pioneering work of Arthur Ashkin and Joseph M. Dziedzic on optical forces exerted on microdroplets. Previously, in the mid-1990s he pioneered studies of synthetic opals as novel three-dimensional photonic crystals for visible light. He has authored and co-authored about 180 research publications and 15 patents which have been cited more than 6000 times.
