Plasmonics and super resolution imaging 1st Edition by Zhaowei Liu 9814669911 9789814669917
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ISBN 10: 9814669911
ISBN 13: 9789814669917
Author: Zhaowei Liu
Plasmonics is an emerging field mainly developed within the past two decades. Due to its unique capabilities to manipulate light at deep subwavelength scales, plasmonics has been commonly treated as the most important part of nanophotonics. Plasmonic-assisted optical microscopy techniques, especially super-resolution microscopy, have shown tremendous potential and attracted much attention. This book aims to collect cutting-edge studies in various optical imaging technologies with advanced performances that are enabled or enhanced by plasmonics. The basic working principles, development details, and potential future direction and perspectives are discussed. Edited by Zhaowei Liu, a prominent researcher in the field of super-resolution microscopy, this book will be an excellent reference for anyone in the field of nanophotonics, plasmonics, and optical microscopy.
Plasmonics and super resolution imaging 1st Table of contents:
1 The Far-Field Superlens
1.1 Introduction
1.1.1 Background
1.1.2 Negative Refraction and the Perfect Lens
1.1.3 The Near-Field Superlens
1.2 One-Dimensional Far-Field Superlens Theory
1.3 One-Dimensional Experimental Demonstration
1.3.1 Verifying the Transfer Function
1.3.2 Building a Far-Field Superlens
1.3.3 Experimental Imaging
1.4 Tuning the Operational Wavelength
1.5 The Two-Dimensional Far-Field Superlens
1.6 Summary
2 Beating the Diffraction Limit with Positive Refraction: The Resonant Metalens Approach
2.1 Introduction
2.2 Principles of the Resonant Metalens
2.2.1 Locally Resonant Metamaterials
2.2.2 Coding the Subwavelength Information of a Source into the Complex Spectrum of a Polychromatic Wave Field
2.2.3 Efficient Conversion of Evanescent Waves to Propagating Ones, Thanks to Resonant Amplification
2.2.4 Applications and Limits of a Resonant Metalens
2.3 Experimental Demonstrations with Microwaves and Sound
2.3.1 Original Demonstration: A Wire Medium-Based Resonant Metalens for Microwave Applications
2.3.2 Moving from Microwaves to Acoustics: A Soda Can-Based Resonant Metalens
2.4 Optical Resonant Metalens with Plasmonic Nanoparticles
2.4.1 Specificity of Light Manipulation
2.4.2 Designing the Plasmonic Resonant Metalens
2.4.3 Far-Field Subwavelength Focusing of Light Using Time Reversal
2.4.4 Polychromatic Interferometric Far-Field Subwavelength Imaging
2.5 Conclusion
3 Ultrathin Metalens and Three-Dimensional Optical Holography Using Metasurfaces
3.1 Introduction
3.2 Ultrathin Metalens
3.2.1 Background
3.2.2 Design Theory and Simulation
3.2.2.1 Required phase profile
3.2.2.2 Simulation method
3.2.2.3 Dual-polarity metalens
3.3 3D Optical Holography Using Metasurfaces
3.3.1 Background
3.3.2 Design and Simulation
3.3.2.1 Computer-generated hologram design
3.3.2.2 Design of a metasurface hologram
3.3.3 Characterization of a Metasurface Hologram
3.3.4 Discussion
3.4 Conclusion
4 Plasmonic Structured Illumination Microscopy
4.1 Introduction
4.1.1 Optical Microscopy and Resolution Limit
4.1.2 Traditional Methods of Improving the Resolving Power
4.2 Super-Resolution Fluorescence Microscopy and Surface Plasmons
4.2.1 Super-Resolution Fluorescence Microscopy Techniques
4.2.2 Structured Illumination Microscopy
4.2.3 Background of Surface Plasmons
4.3 Principles of Plasmonic Structured Illumination Microscopy
4.3.1 Surface Plasmon Interference Formation and Manipulation
4.3.2 PSIM Image Reconstruction Method
4.4 PSIM Demonstration
4.4.1 Numerical Demonstration of PSIM
4.4.2 Experimental Demonstration of PSIM
4.4.3 Discussion
4.5 Localized Plasmonic Structured Illumination Microscopy
4.6 Perspective and Outlook
5 Optical Super-Resolution Imaging Using Surface Plasmon Polaritons
5.1 Introduction
5.2 Surface Plasmon Microscopy
5.3 The Surface Plasmon Hyperlens
5.4 Surface Plasmon Microscope Operation in the Geometric Optics Mode
5.5 Conventional Plasmon Focusing Devices
5.6 Conclusion
6 Hyperlenses and Metalenses
6.1 Introduction
6.2 Physics of the Hyperlens
6.3 Experimental Demonstration of the Hyperlens
6.4 Working Mechanism of the Metalens
6.5 Metalens Demonstration
6.5.1 Design of the Metalens: Plane Wave Focusing for Optical Fourier Transform
6.5.2 Extraordinary Imaging Properties of the Hyperbolic Metalens
6.6 Hyperlenses for Acoustic Waves
6.7 Perspectives and Outlook
7 Modeling Linear and Nonlinear Hyperlens Structures
7.1 Motivation
7.2 Background
7.2.1 The Hyperlens
7.2.2 Nonlinear Optics
7.3 Numerical Techniques and Algorithms
7.3.1 The Beam Propagation Method
7.3.2 The Cylindrical Beam Propagation Method
7.3.3 The Nonlinear Beam Propagation Method
7.3.4 The Finite Difference Method
7.3.5 The Cylindrical Transfer Matrix Method
7.4 The Nonlinear Hyperlens
7.4.1 The Perfect Imaging Condition
7.4.2 Diffraction Loss Trade-Off
7.4.3 Nonlinear Hyperlens Simulations
7.4.4 Conclusions
7.5 The Validity of the EMT in Cylindrical Coordinates
7.5.1 The Cylindrical Amplitude Transfer Function
7.5.2 The Mean Square Approximation Error
7.6 Conclusions
8 Nanoparticle-Assisted Stimulated Emission Depletion (STED) Super-Resolution Nanoscopy
8.1 Prologue: A Eulogy to a Friend
8.2 Introduction
8.3 Principles of STED Nanoscopy
8.3.1 Qualitative Description
8.3.2 Quantitative Description
8.4 Light Interaction with Metal Nanoparticles
8.5 Principles of NP-STED Nanoscopy
8.5.1 Qualitative Discussion
8.5.2 Quantitative Discussion
8.5.3 Design Considerations for NP-STED Fluorescent Labels
8.5.4 Ideal NP-STED Illumination
8.5.5 Example: Metal Nanoshells
8.6 Experimental Results
8.7 Methods
8.7.1 Numerical Calculations
8.7.2 Experimental STED Nanoscopy System
8.8 Summary and Outlook
9 Lab-on-Antennas: Plasmonic Antennas for Single-Molecule Spectroscopy
9.1 Introduction
9.1.1 Nanofocusing
9.2 Reducing the Focus Volume
9.2.1 Probing the Focus Volume with Single-Molecule Super-Resolution Imaging
9.2.2 Plasmonic Antennas for High-Concentration SMS
9.3 Suppressing Photobleaching
9.3.1 Photobleaching Limits the Resolution of SMS
9.3.2 The Plasmonic Purcell Effect
9.3.3 The Kinetic Model of Photobleaching Suppression
9.3.4 Numerical Simulation of Plasmonic Antennas for Photobleaching Suppression
9.3.5 Experimental Observation
9.4 Summary and Prospects
10 Plasmonic Lenses for High-Throughput Nanolithography
10.1 Introduction to Maskless Nanolithography
10.2 Introduction to Plasmonic Nanofocusing Structures
10.3 Plasmonic Lenses
10.4 Scanning Plasmonic Lenses in the Near Field
10.5 Summary
11 Plasmonic Nanoresonators for Spectral Color Filters and Structural Colored Pigments
11.1 Introduction and Motivation
11.2 Transmission Filters Based on MIM Nanoresonators
11.3 Metallic Resonant Waveguide Grating Color Filters
11.4 Angle-Insensitive Plasmonic Spectrum Filtering
11.5 Wide-Angled Transmission Plasmonic Color Filters
11.5.1 Color Purity and Suppression of Off-Resonance Transmission
11.5.2 Effect of Coupling between the Nanoresonator and Grating Resonance
11.5.3 Angle Dependence of the Coupled Resonance
11.5.4 Achieving Angle-Insensitive Spectrum Filter in the Slit Nanoresonator Array Structure
11.6 Ultrathin Metallic Nanoresonators for Angle-Insensitive Reflective Colors
11.7 Angle-Insensitive Colors Utilizing Highly Absorbing Materials
11.8 Future Outlook
12 Plasmonic Microscopy for Biomedical Imaging
12.1 Introduction
12.2 Metal Film Preparations
12.3 SPR Phase Microscopy
12.3.1 DNA Microarray Sensing
12.3.2 Cell-Biosubstrate Contacts
12.4 Fluorescence-Enhanced Microscopy
12.4.1 One-Photon Excited Fluorescence-Enhanced Imaging
12.4.2 Two-Photon Excited Fluorescence-Enhanced Imaging
12.4.3 Fluorescence Enhancement and Quenching
12.5 Combination of SPR Phase and Fluorescence-Enhanced Imaging
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Zhaowei Liu,Plasmonics,super,resolution