Nano-Optics
Published on 23. April 2002
Book
Hardback
XV, 324 pages
978-3-540-41829-0 (ISBN)
Description
This book deals with an important nano-optical technique, optical near-field microscopy. It presents the most advanced application of this technique to studies of fine metallic structures and related surface plasmons.
More details
Series
Edition
2002 ed.
Language
English
Place of publication
Berlin
Germany
Publishing group
Springer Berlin
Target group
Professional and scholarly
Research
Illustrations
XV, 324 p.
Dimensions
Height: 241 mm
Width: 160 mm
Thickness: 24 mm
Weight
682 gr
ISBN-13
978-3-540-41829-0 (9783540418290)
DOI
10.1007/978-3-540-45273-7
Schweitzer Classification
Other editions
Additional editions
Satoshi Kawata | Motoichi Ohtsu | Masahiro Irie
Nano-Optics
Book
09/2011
Springer
€160.49
Shipment within 7-9 days
Content
1 Quantum Theory for Near-Field Nano-Optics.- 1.1 Resonant Near-Field Optics.- 1.2 Quantization of Evanescent Waves and Optical Near-Rield Interaction of Atoms.- 1.3 Quantum Mechanical Aspects of Optical Near-Field Problems.- 2 Electromagnetism Theory and Analysis for Near-Field Nano-Optics.- 2.1 Finite-Difference Time-Domain Analysis of a Near-Field Microscope System.- 2.2 Reconstruction of an Optical Image from NSOM Data.- 2.3 Radiation Force Exerted near a Nano-Aperture.- References.- 3 High-Resolution and High-Throughput Probes.- 3.1 Excitation of a HE-Plasmon Mode.- 3.2 Multiple-Tapered Probes.- References.- 4 Apertureless Near-Field Probes.- 4.1 Local Plasmon in a Metallic Nanoparticle.- 4.2 Laser-Trapping of a Metallic Particle for a Near-Field Microscope Probe.- 4.3 Near-Field Enhancement at a Metallic Probe.- 4.4 Scattering Near-Field Optical Microscope with a Microcavity.- References.- 5 Integrated and Functional Probes.- 5.1 Micromachined Probes.- 5.2 Light Detection from Force.- 5.3 High Efficiency Light Transmission Through a Nano-Waveguide.- References.- 6 High-Density Optical Memory and Ultrafine Photofabrication.- 6.1 Photochromic Memory Media.- 6.2 Near-Field Optical Memory.- 6.3 Future Prospects for Near-Field Optical Memory.- 6.4 Nanofabrication: Chemical Vapor Deposition.- 6.5 Nanofabrication: Organic Film.- References.- 7 Near-Field Imaging of Molecules and Thin Films.- 7.1 Near-Field Imaging of Molecules and Thin Films.- 7.2 Two-Dimensional Morphology of Ultrathin Polymer Films.- 7.3 Observation of Polyethylene (PE) Crystals.- 7.4 Preparation of Micrometer-Sized Chromophore Aggregates.- 7.5 Application to Electrochemical Research.- 7.6 Second-Harmonic Generation in Near-Field Optics.- References.- 8 Near-Field Microscopy for Biomolecular Systems.-8.1 Near-Field Imaging of Human Chromosomes and Single DNA Molecules.- 8.2 Imaging of Biological Molecules.- 8.3 Cell and Cellular Functions.- References.- 9 Near-Field Imaging of Quantum Devices and Photonic Structures.- 9.1 Spectroscopy of Quantum Devices and Structures.- 9.2 Observation of Polysilane by Near-Field Scanning Optical Microscope in the Ultraviolet (UV) Region.- 9.3 Near-Field Photon Tunneling.- References.- 10 Other Imaging and Applications.- 10.1 Birefringent Imaging with an Illumination-Mode Near-Field Scanning Optical Microscope.- 10.2 Plain-Type Low-Temperature NSOM System.- 10.3 STM-Induced Luminescence.- 10.4 Energy Modulation of Electrons with Evanescent Waves.- 10.5 Manipulation of Particles by Photon Force.- References.