عنوان
پدید آورنده
موضوع
رده
کتابخانه
محل استقرار
INTERNATIONAL STANDARD BOOK NUMBER
(Number (ISBN
1351004883
(Number (ISBN
1498779808
(Number (ISBN
9781351004886
(Number (ISBN
9781498779807
NATIONAL BIBLIOGRAPHY NUMBER
Number
b383591
TITLE AND STATEMENT OF RESPONSIBILITY
Title Proper
Self-Organized Lightwave Networks :
General Material Designation
[Book]
Other Title Information
Self-Aligned Coupling Optical Waveguides.
.PUBLICATION, DISTRIBUTION, ETC
Place of Publication, Distribution, etc.
Milton
Name of Publisher, Distributor, etc.
Chapman and Hall/CRC,
Date of Publication, Distribution, etc.
2018.
PHYSICAL DESCRIPTION
Specific Material Designation and Extent of Item
(265 pages)
GENERAL NOTES
Text of Note
7.2.2 Waveguide-Type Thin-Film Artificial Photosynthesis Cell.
CONTENTS NOTE
Text of Note
Cover Half Title Title Page Copyright Page Dedication Contents Preface Author Chapter 1: Introduction Chapter 2: Related Technologies 2.1 Self-Focusing of Lightwaves in Nonlinear Optical Media 2.2 Self-Written Waveguides (SWWs) References Chapter 3: Concepts and Features of Self-Organized Lightwave Networks (SOLNETs) 3.1 Types of SOLNETs 3.2 PRI Materials 3.3 One-Photon and Two-Photon SOLNETs 3.4 Fabrication Processes of Targets and Phosphor-Doped Regions References Chapter 4: Performance of SOLNETs Predicted by Computer Simulations. 4.1 SOLNETs between Microscale Waveguides4.1.1 TB-SOLNET/P-SOLNET 4.1.1.1 Couplings between Waveguides with Same Core Size 4.1.1.2 Couplings between Waveguides with Different Core Sizes 4.1.2 R-SOLNET 4.2 SOLNETs between Nanoscale Waveguides 4.2.1 Simulation Models and Procedures 4.2.2 Butt Joint 4.2.3 TB-SOLNET/P-SOLNET 4.2.4 R-SOLNET 4.2.5 LA-SOLNET 4.2.6 Performance of Couplings 4.3 SOLNETs between Microscale and Nanoscale Waveguides 4.3.1 Simulation Models and Procedures 4.3.2 Butt Joint 4.3.3 TB-SOLNET/P-SOLNET 4.3.4 R-SOLNET 4.3.5 LA-SOLNET. 4.3.6 Performance of Couplings4.4 Influence of Write-Beam Wavelengths on SOLNET Formation 4.5 Influence of Write-Beam Intensity and Gap Distances on SOLNET Formation 4.5.1 Write-Beam Intensity 4.5.2 Gap Distances 4.6 Vertical SOLNETs 4.6.1 L-Shaped SWW 4.6.2 R-SOLNET with Wavelength Filters 4.6.3 Vertical R-SOLNET 4.7 Parallel SOLNETs 4.7.1 Comparison of Parallel R-SOLNETs and SWWs 4.7.2 Misalignment Tolerance in Parallel R-SOLNETs 4.8 Y-Branching SOLNETs 4.8.1 Y-Branching TB-SOLNET 4.8.2 Y-Branching R-SOLNET References. Chapter 5: Preferable Waveguide Growth Condition for SOLNET Formation5.1 Straight Waveguide Growth 5.2 Vertical Waveguide Growth 5.3 Influence of Write-Beam Absorption and Intensity on Waveguide Growth 5.3.1 Write-Beam Absorption 5.3.2 Write-Beam Intensity References Chapter 6: Experimental Demonstrations of SOLNETs 6.1 TB-SOLNETs 6.2 R-SOLNETs 6.2.1 R-SOLNET Formed by a Free-Space Write Beam 6.2.2 R-SOLNET with Micromirrors 6.2.3 R-SOLNET with Reflective Objects 6.2.4 R-SOLNET with Luminescent Targets 6.2.4.1 Coumarin-481 Luminescent Targets 6.2.4.2 Alq3 Luminescent Targets. 6.3 Y-Branching SOLNETs6.4 Two-Photon SOLNETs 6.4.1 Two-Photon TB-SOLNET 6.4.2 Two-Photon R-SOLNET References Chapter 7: Applications of SOLNETs 7.1 Integrated Optical Interconnects and Switching Systems 7.1.1 Scalable Film Optical Link Module (S-FOLM) 7.1.2 3D OE Platform Built by Self-Organized Optical Wiring 7.1.3 Self-Organized 3D-Integrated Optical Interconnects 7.1.4 Self-Organized 3D-MOSS 7.1.5 Effect of SOLNET on Insertion Loss in 3D-MOSS 7.2 Integrated Solar Energy Conversion Systems 7.2.1 Waveguide-Type Thin-Film Sensitized Solar Cell.
CORPORATE BODY NAME USED AS SUBJECT
Electronic books
PERSONAL NAME - PRIMARY RESPONSIBILITY
Tetsuzo Yoshimura
ELECTRONIC LOCATION AND ACCESS
Electronic name
مطالعه متن کتاب [Book]
Y
