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図書

図書
Geoffrey A. Ozin and Andre C. Arsenault
出版情報: Cambridge, UK : Royal Society of Chemistry, c2005  xl, 628 p. ; 25 cm
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List of Acronyms
Teaching (Nano)Materials
Learning (Nano)Materials
About the Authors
Acknowledgements
Nanofood for Thought - Thinking about Nanochemistry, Nanoscience, Nanotechnology and Nanosafety
Nanochemistry Basics / Chapter 1:
Materials Self-Assembly / 1.1:
Big Bang to the Universe / 1.2:
Why Nano? / 1.3:
What do we Mean by Large and Small Nanomaterials? / 1.4:
Do it Yourself Quantum Mechanics / 1.5:
What is Nanochemistry? / 1.6:
Molecular vs. Materials Self-Assembly / 1.7:
What is Hierarchical Assembly? / 1.8:
Directing Self-Assembly / 1.9:
Supramolecular Vision / 1.10:
Geneology of Self-Assembling Materials / 1.11:
Unlocking the Key to Porous Solids / 1.12:
Learning from Biominerals - Form is Function / 1.13:
Can you Curve a Crystal? / 1.14:
Patterns, Patterns Everywhere / 1.15:
Synthetic Creations with Natural Form / 1.16:
Two-Dimensional Assemblies / 1.17:
SAMs and Soft Lithography / 1.18:
Clever Clusters / 1.19:
Extending the Prospects of Nanowires / 1.20:
Coercing Colloids / 1.21:
Mesoscale Self-Assembly / 1.22:
Materials Self-Assembly of Integrated Systems / 1.23:
References / 1.24:
Nanofood for Thought - Nanochemistry, Genealogy Materials Self-Assembly, Length Scales
Chemical Patterning and Lithography / Chapter 2:
Soft Lithography / 2.1:
What are Self-Assembled Monolayers? / 2.2:
The Science and Art of Soft Lithography / 2.3:
Patterning Wettability? / 2.4:
Condensation Figures / 2.5:
Microlens Arrays / 2.6:
Nanoring Arrays / 2.7:
Patterning the Solid State / 2.8:
Primed for Printing Polymers / 2.9:
Beyond Molecules - Transfer Printing of Thin Films / 2.10:
Electrically Contacting SAMS / 2.11:
SAM Crystal Engineering / 2.12:
Learning from Nature's Biocrystal Engineering / 2.13:
Colloidal Microsphere Patterns / 2.14:
Switching SAM Function / 2.15:
Patterning by Photocatalysis / 2.16:
Reversibly Switching SAMs / 2.17:
Electrowettability Switch / 2.18:
Sweet Chips / 2.19:
All Fall Down in a Row Lithography / 2.20:
Nanofood for Thought - Soft Lithography, SAMs, Patterning / 2.21:
Layer-by-Layer Self-Assembly / Chapter 3:
Building One Layer at a Time / 3.1:
Electrostatic Superlattices / 3.2:
Organic Polyelectrolyte Multilayers / 3.3:
Layer-by-Layer Smart Windows / 3.4:
How Thick is Thin? / 3.5:
Assembling Metallopolymers / 3.6:
Directly Imaging Polyelectrolyte Multilayers / 3.7:
Polyelectrolyte-Colloid Multilayers / 3.8:
Graded Composition LbL Films / 3.9:
LbL MEMS / 3.10:
Trapping Active Proteins / 3.11:
Layering on Curved Surfaces / 3.12:
Crystal Engineering of Oriented Zeolite Film / 3.13:
Zeolite-Ordered Multicrystal Arrays / 3.14:
Crosslinked Crystal Arrays / 3.15:
Layering with Topological Complexity / 3.16:
Patterned Multilayers / 3.17:
Non-Electrostatic Layer-by-Layer Assembly / 3.18:
Low Pressure Layers / 3.19:
Layer-by-Layer Self-Limiting Reactions / 3.20:
Nanofood for Thought - Designer Monolayers, Multilayers, Materials Flatland / 3.21:
Nanocontact Printing and Writing - Stamps and Tips / Chapter 4:
Sub-100 nm Soft Lithography / 4.1:
Extending Microcontact Printing / 4.2:
Putting on the Pressure / 4.3:
Defect Patterning - Topologically Directed Etching / 4.4:
Below 50 nm Nanocontact Printing / 4.5:
Nanocontact Writing - Dip Pen Nanolithography / 4.6:
DPN of Silicon / 4.7:
DPN on Glass / 4.8:
Nanoscale Writing on Seminconductor Nanowires / 4.9:
Sol-Gel DPN / 4.10:
Soft Patterning of Hard Magnets / 4.11:
Writing Molecular Recognition / 4.12:
DPN Writing Protein Recognition Nanostructures / 4.13:
Patterning Bioconstructions / 4.14:
Eating Patterns - Enzyme DPN / 4.15:
Electrostatic DPN / 4.16:
Electrochemical DPN / 4.17:
SPM Nano-Electrochemistry / 4.18:
Beyond DPN - Whittling Nanostructures / 4.19:
Combi Nano - DPN Combinatorial Libraries / 4.20:
Nanoplotters / 4.21:
Nanoblotters / 4.22:
Scanning Probe Contact Printing (SP-CP) / 4.23:
Dip Pen Nanolithography Stamp Tip - Beyond DPN CP / 4.24:
Best of Both Worlds / 4.25:
The Nanogenie is out of the Bottle / 4.26:
Nanofood for Thought - Sharper Chemical Patterning Tools / 4.27:
Nanorod, Nanotube, Nanowire Self-Assembly / Chapter 5:
Building Block Assembly / 5.1:
Templating Nanowires / 5.2:
Modulated Diameter Gold Nanorods / 5.3:
Modulated Composition Nanorods / 5.4:
Barcoded Nanorod Orthogonal Self-Assembly / 5.5:
Self-Assembling Nanorods / 5.6:
Magnetic Nanorods Bunch Up / 5.7:
Magnetic Nanorods and Magnetic Nanoclusters / 5.8:
An Irresistable Attraction for Biomolecules / 5.9:
Hierarchically Ordered Nanorods / 5.10:
Nanorod Devices / 5.11:
Nanotubes from Nanoporous Templates / 5.12:
Layer-by-Layer Nanotubes from Nanorods / 5.13:
Synthesis of Single Crystal Semiconductor Nanowires / 5.14:
Vapor-Liquid-Solid Synthesis of Nanowires / 5.15:
What Controls Nanowire-Oriented Growth? / 5.16:
Supercritical Fluid-Liquid-Solid Synthesis / 5.17:
Nanowire Quantum Size Effects / 5.18:
Zoo of Nanowire Compositions and Architectures / 5.19:
Single-Source Precursors / 5.20:
Manipulating Nanowires / 5.21:
Crossed Semiconductor Nanowires - Smallest LED / 5.22:
Nanowire Diodes and Transistors / 5.23:
Nanowire Sensors / 5.24:
Catalytic Nanowire Electronics / 5.25:
Nanowire Heterostructures / 5.26:
Longitudinal Nanowire Superlattices / 5.27:
Axial Nanowire Heterostructures / 5.28:
Nanowires Branch Out / 5.29:
Coaxially Gated Nanowire Transistor / 5.30:
Vertical Nanowire Field Effect Transistors / 5.31:
Integrated Metal-Semiconductor Nanowires - Nanoscale Electrical Contacts / 5.32:
Photon-Driven Nanowire Laser / 5.33:
Electrically Driven Nanowire Laser / 5.34:
Nanowire UV Photodetectors / 5.35:
Simplifying Complex Nanowires / 5.36:
Nanowire Casting of Single-Crystal Nanotubes / 5.37:
Solution-Phase Routes to Nanowires / 5.38:
Spinning Nanowire Devices / 5.39:
Hollow Nanofibers by Electrospinning / 5.40:
Carbon Nanotubes / 5.41:
Carbon Nanotube Structure and Electrical Properties / 5.42:
Gone Ballistic / 5.43:
Carbon Nanotube Nanomechanics / 5.44:
Carbon Nanotube Chemistry / 5.45:
Carbon Nanotubes All in a Row / 5.46:
Carbon Nanotube Photonic Crystal / 5.47:
Putting Carbon Nanotubes Exactly Where You Want Them / 5.48:
The Nanowire Pitch Challenge / 5.49:
Integrated Nanowire Nanoelectronics / 5.50:
A Small Thought at the End of a Large Chapter / 5.51:
Nanofood for Thought - Wires, Rods, Tubes, Low Dimensionality / 5.52:
Nanocluster Self-Assembly / Chapter 6:
Building-Block Assembly / 6.1:
When is a Nanocluster a Nanocrystal or Nanoparticle? / 6.2:
Synthesis of Capped Semiconductor Nanoclusters / 6.3:
Electrons and Holes in Nanocluster Boxes / 6.4:
Watching Nanoclusters Grow / 6.5:
Nanocrystals in Nanobeakers / 6.6:
Nanocluster Semiconductor Alloys and Beyond / 6.7:
Nanocluster Phase Transformation / 6.8:
Capped Gold Nanoclusters - Nanonugget Rush / 6.9:
Alkanethiolate Capped Nanocluster Diagnostics / 6.10:
Periodic Table of Capped Nanoclusters / 6.11:
There's Gold in Them Thar Hills! / 6.12:
Water-Soluble Nanoclusters / 6.13:
Capped Nanocluster Architectures and Morphologies / 6.14:
Alkanethiolate Capped Silver Nanocluster Superlattice / 6.15:
Crystals of Nanocrystals / 6.16:
Beyond Crystal of Nanocrystals - Binary Nanocrystal Superlattices / 6.17:
Capped Magnetic Nanocluster Superlattice - High Density Data Storage Materials / 6.18:
Alloying Core-Shell Magnetic Nanoclusters / 6.19:
Soft Lithography of Capped Nanoclusters / 6.20:
Organizing Nanoclusters by Evaporation / 6.21:
Electroluminescent Semiconductor Nanoclusters / 6.22:
Full Color Nanocluster-Polymer Composites / 6.23:
Capped Semiconductor Nanocluster Meets Biomolecule / 6.24:
Nanocluster DNA Sensors - Besting the Best / 6.25:
Semiconductor Nanoclusters Extend and Branch Out / 6.26:
Branched Nanocluster Solar Cells / 6.27:
Tetrapod of Tetrapods - Towards Inorganic Dendrimers / 6.28:
Golden Tips - Making Contact with Nanorods / 6.29:
Flipping a Nanocluster Switch / 6.30:
Photochromic Metal Nanoclusters / 6.31:
Carbon Nanoclusters - Buckyballs / 6.32:
Building Nanodevices with Buckyballs / 6.33:
Carbon Catalysis with Buckyball / 6.34:
Nanofood for Thought - Nanoclusters, Nanocrystals, Quantum Dots, Quantum Size Effects / 6.35:
Microspheres - Colors from the Beaker / Chapter 7:
Nature's Photonic Crystals / 7.1:
Photonic Crystals / 7.2:
Photonic Semiconductors / 7.3:
Defects, Defects, Defects / 7.4:
Computing with Light / 7.5:
Color Tunability / 7.6:
Transferring Nature's Photonic Crystal Technology to the Chemistry Laboratory / 7.7:
Microsphere Building Blocks / 7.8:
Silica Microspheres / 7.9:
Latex Microspheres / 7.10:
Multi-Shell Microspheres / 7.11:
Basics of Microsphere Self-Assembly / 7.12:
Microsphere Self-Assembly - Crystals and Films / 7.13:
Colloidal Crystalline Fluids / 7.14:
Beyond Face Centered Cubic Packing of Microspheres / 7.15:
Templates - Confinement and Epitaxy / 7.16:
Photonic Crystal Fibers / 7.17:
Photonic Crystal Marbles / 7.18:
Optical Properties of Colloidal Crystals - Combined Bragg-Snell Laws / 7.19:
Basic Optical Properties of Colloidal Crystals / 7.20:
How Perfect is Perfect? / 7.21:
Cracking Controversy / 7.22:
Synthesizing a Full Photonic Band Gap / 7.23:
Writing Defects / 7.24:
Getting Smart with Planar Defects / 7.25:
Switching Light with Light / 7.26:
Internal Light Sources / 7.27:
Photonic Inks / 7.28:
Color Oscillator / 7.29:
Photonic Crystal Sensors / 7.30:
Colloidal Photonic Crystal Solar Cell / 7.31:
Thermochromic Colloidal Photonic Crystal Switch / 7.32:
Liquid Crystal Photonic Crystal / 7.33:
Encrypted Colloidal Crystals / 7.34:
Gazing into the Photonic Crystal Ball / 7.35:
Nanofood for Thought - Colloidal Assembly, Colloidal Crystals, Colloidal Crystal Devices, Structural Color / 7.36:
Microporous and Mesoporous Materials from Soft Building Blocks / Chapter 8:
Escape from the Zeolite Prison / 8.1:
A Periodic Table of Materials Filled with Holes / 8.2:
Modular Self-Assembly of Microporous Materials / 8.3:
Hydrogen Storage Coordination Frameworks / 8.4:
Overview and Prospects of Microporous Materials / 8.5:
Mesoscale Soft Building Blocks / 8.6:
Micelle Versus Liquid Crystal Templating Paradox / 8.7:
Designing Function into Mesoporous Materials / 8.8:
Tuning Length Scales / 8.9:
Mesostructure and Dimensionality / 8.10:
Mesocomposition - Nature of Precursors / 8.11:
Mesotexture / 8.12:
Periodic Mesoporous Silica-Polymer Hybrids / 8.13:
Guests in Mesopores / 8.14:
Capped Nanocluster Meets Surfactant Mesophase / 8.15:
Marking Time in Mesostructured Silica - New Approach to Optical Data Storage / 8.16:
Sidearm Mesofunctionalization / 8.17:
Organics in the Backbone / 8.18:
Mesomorphology - Films, Interfaces, Mesoepitaxy / 8.19:
Stand Up and Be Counted / 8.20:
Mesomorphology - Spheres, Other Shapes / 8.21:
Mesomorphology - Patterned Films, Soft Lithography, Micromolding / 8.22:
Mesomorphology - Morphosynthesis of Curved Form / 8.23:
Chiral Surfactant Micelles - Chiral Mesoporous Silica / 8.24:
Mesopore Replication / 8.25:
Mesochemistry and Topological Defects / 8.26:
Mesochemistry - Synthesis in "Intermediate" Dimensions / 8.27:
Nanofood for Thought - Soft Blocks Template Hard Precursors, Holey Materials / 8.28:
Self-Assembling Block Copolymers / Chapter 9:
Polymers, Polymers Everywhere in Nanochemistry / 9.1:
Block Copolymer Self-Assembly - Chip Off the Old Block / 9.2:
Nanostructured Ceramics / 9.3:
Nano-objects / 9.4:
Block Copolymer Thin Films / 9.5:
Electrical Ordering / 9.6:
Spatial Confinement of Block Copolymers / 9.7:
Nanoepitaxy / 9.8:
Block Copolymer Lithography / 9.9:
Decorating Block Copolymers / 9.10:
A Case of Wettability / 9.11:
Nanowires from Block Copolymers / 9.12:
Making Micelles / 9.13:
Assembling Inorganic Polymers / 9.14:
Harnessing Rigid Rods / 9.15:
Supramolecular Assemblies / 9.16:
Supramolecular Mushrooms / 9.17:
Structural Color from Lightscale Block Copolymers / 9.18:
Block Copolypeptides / 9.19:
Block Copolymer Biofactories / 9.20:
Nanofood for Thought - Block Copolymer Self-Assembling Nanostructures / 9.21:
Biomaterials and Bioinspiration / Chapter 10:
Nature did it First / 10.1:
To Mimic or to Use? / 10.2:
Faux Fossils / 10.3:
Nature's Siliceous Sculptures / 10.4:
Ancient to Modern Synthetic Morphology / 10.5:
Biomimicry / 10.6:
Biomineralization and Biomimicry Analogies / 10.7:
Learning from Nature / 10.8:
Viral Cage Directed Synthesis of Nanoclusters / 10.9:
Viruses that Glitter / 10.10:
Polynucleotide Directed Nanocluster Assembly / 10.11:
DNA Coded Nanocluster Chains / 10.12:
Building with DNA / 10.13:
Bacteria Directed Materials Self-Assembly / 10.14:
Using a Virus that is Benign, to Align / 10.15:
Magnetic Spider Silk / 10.16:
Protein S-Layer Masks / 10.17:
Morphosynthesis - Inorganic Materials with Complex Form / 10.18:
Echinoderm vs. Block Copolymers / 10.19:
Fishy Top-Down Photonic Crystals / 10.20:
Aluminophosphates Shape Up / 10.21:
Better Bones Through Chemistry / 10.22:
Mineralizing Nanofibers / 10.23:
Biological Lessons in Materials Design / 10.24:
Surface Binding Through Directed Evolution / 10.25:
Nanowire Evolution / 10.26:
Biomolecular Motors - Nanomachines Everywhere / 10.27:
How Biomotors Work / 10.28:
Kinesin - Walk Along / 10.29:
ATPase - Biomotor Nanopropellors / 10.30:
(Bio)Inspiration / 10.31:
Nanofood for Thought - Organic Matrix, Biomineralization, Biomimetics, Bioinspiration / 10.32:
Self-Assembly of Large Building Blocks / Chapter 11:
Self-assembling Supra-micron Shapes / 11.1:
Synthesis Using the "Capillary Bond" / 11.2:
Crystallizing Large Polyhedral-Shaped Building Blocks / 11.3:
Self-Assembling 2D and 3D Electrical Circuits and Devices / 11.4:
Crystallizing Micron-Sized Planar Building Blocks / 11.5:
Polyhedra with Patterned Faces that Autoconstruct / 11.6:
Large Sphere Building Blocks Self-Assemble into 3D Crystals / 11.7:
Synthetic MEMS? / 11.8:
Magnetic Self-Assembly / 11.9:
Dynamic Self-Assembly / 11.10:
Autonomous Self-Assembly / 11.11:
Self-Assembly and Synthetic Life / 11.12:
Nanofood for Thought - Static and Dynamic, Capillary Bond, Shape Assembly / 11.13:
Nano and Beyond / Chapter 12:
Assembling the Future / 12.1:
Microfluidic Computing / 12.2:
Fuel Cells - Hold the Membrane / 12.3:
Curved Prints / 12.4:
Beating the Ink Diffusion Dilemma / 12.5:
Tip of the Pyramid / 12.6:
Biosensing Membranes / 12.7:
Crossing Nanowires / 12.8:
Complete Crystallographic Control / 12.9:
Down to the Wire / 12.10:
Shielded Nanowires / 12.11:
Writing 3D Nanofluidic and Nanophotonic Networks / 12.12:
Break-and-Glue Transistor Assembly / 12.13:
Turning Nanostructures Inside-out / 12.14:
Confining Spheres / 12.15:
Escape from the Silica and Polystyrene Prison / 12.16:
Smart Dust / 12.17:
Light Writing for Light Guiding / 12.18:
Nanoring Around the Collar / 12.19:
A Meso Rubbed Right / 12.20:
Fungus with the Midas Touch / 12.21:
Self-assembled Electronics / 12.22:
Gears Sink Their Teeth into the Interface / 12.23:
Materials Retro-assembly / 12.24:
Matter that Matters - Materials of the "Next Kind" / 12.25:
Nanofood for Thought - Nano Potpourri / 12.26:
Nanochemistry Nanolabs / Chapter 13:
Origin of the Term "Self-Assembly" / Appendix A:
Cytotoxicity of Nanoparticles / Appendix B:
Walking Macromolecules Through Colloidal Crystals / Appendix C:
Patterning Nanochannel Alumina Membranes With Single Channel Resolution / Appendix D:
Muscle Powered Nanomachines / Appendix E:
Bacteria Power / Appendix F:
Chemically Driven Nanorod Motors / Appendix G:
Subject Index
List of Acronyms
Teaching (Nano)Materials
Learning (Nano)Materials
2.

図書

図書
editors, J. Anthony C. Bland, Adrian Ionescu
出版情報: New York : American Institute of Physics, 2008  xix, 196 p. ; 25 cm
シリーズ名: AIP conference proceedings ; 1025
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Preface
Introduction
Magnetic Entities and Materials for Biomedical Applications / Part 1:
Magnetic Biosensors-From Molecule to System / M. W. J. Prins
The In-flow Capture of Superparamagnetic Nanoparticles for Targeting of Gene Therapeutics / N. J. Darton ; B. Hallmark ; X. Han ; S. Palit ; M. R. Mackley ; D. Darling ; F. Farzaneh ; N. K. H. Slater
Progress in Using Magnetic Nanoobjects for Biomedical Diagnostics / N. Kataeva ; J. Schotter ; A. Shoshi ; R. Heer ; M. Eggeling ; O. Bethge ; C. Nohammer ; H. Bruckl
Templated Growth and Selective Functionalization of Magnetic Nanowires / F. van Belle ; J. J. Palfreyman ; W. S. Lew ; T. Mitrelias ; J. A. C. Bland
Controlled Manipulation of Nanoentities in Suspension / D. L. Fan ; R. C. Cammarata ; C. L. Chien
Digitally Encoded Exchange Biased Multilayers / M. Barbagallo ; A. Ionescu
Magnetic Microtags and Magnetic Encoding for Applications in Biotechnology / T. Trypiniotis ; K. P. Kopper ; S. J. Steinmuller ; P. A. Robertson
High Throughput Biological Analysis Using Multi-bit Magnetic Digital Planar Tags / B. Hong ; J.-R. Jeong ; J. Llandro ; T. J. Hayward
Magnetically Controlled Shape Memory Behaviour-Materials and Applications / A. P. Gandy ; A. Sheikh ; K. Neumann ; K.-U. Neumann ; D. Pooley ; K. R. A. Ziebeck
Magnetic Biosensors and Detection Systems / Part 2:
Giant Magnetoresistive Biochips for Biomarker Detection and Genotyping: An Overview / S. X. Wang
Towards Magnetic Suspension Assay Technology / C. H. W. Barnes
Detection of Magnetic-based Biomolecules Using MR Sensors / M. Volmer ; M. Avram
Giant Magnetoimpedance for Biosensing in Drug Delivery / V. Fal-Miyar ; A. Kumar ; S. Mohapatra ; S. Shirley ; N. A. Frey ; J. M. Barandiaran ; G. V. Kurlyandskaya
Residence Times Difference Fluxgate Magnetometer for Magnetic Biosensing / B. Ando ; A. Ascia ; S. Baglio ; A. R. Bulsara ; V. In ; N. Pitrone ; C. Trigona
Integrated Spintronic Platforms for Biomolecular Recognition Detection / V. C. Martins ; F. A. Cardoso ; J. Loureiro ; M. Mercier ; J. Germano ; S. Cardoso ; R. Ferreira ; L. P. Fonesca ; L. Sousa ; M. S. Piedade ; P. P. Freitas
Moment Selective Digital Detection of Single Magnetic Beads for Multiplexed Bioassays / D. Morecroft ; F. J. Castano ; I. A. Colin ; C. A. Ross
Advanced Magnetoresistance Sensing of Rotation Rate for Biomedical Applications / A. Avram
Author Index
Preface
Introduction
Magnetic Entities and Materials for Biomedical Applications / Part 1:
3.

図書

図書
edited by Sam Zhang
出版情報: Boca Raton : CRC Press, c2010  xi, 241 p. ; 26 cm
シリーズ名: Handbook of nanostructured thin films and coatings / edited by Sam Zhang
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4.

図書

図書
edited by Sam Zhang
出版情報: Boca Raton : CRC Press, c2010  xii, 538 p. ; 26 cm
シリーズ名: Handbook of nanostructured thin films and coatings / edited by Sam Zhang
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5.

図書

図書
edited by Christian Hess and Robert Schlögl
出版情報: Cambridge [UK] : Royal Society of Chemistry, c2011  xiv, 438 p. ; 24 cm
シリーズ名: RSC nanoscience & nanotechnology ; no. 19
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6.

図書

図書
edited by Challa S. S. R. Kumar
出版情報: Weinheim : Wiley-VCH, c2010  xx, 445 p. ; 25 cm
シリーズ名: Nanomaterials for the life sciences / edited by Challa S.S.R. Kumar ; v. 8
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7.

図書

図書
edited by Challa S. S. R. Kumar
出版情報: Weinheim : Wiley-VCH, c2010  xxii, 564 p. ; 25 cm
シリーズ名: Nanomaterials for the life sciences / edited by Challa S.S.R. Kumar ; v. 7
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8.

図書

図書
Lei Jiang, Lin Feng
出版情報: Beijing : Chemical Industry Press , Singapore : World Scientific, c2010  xiii, 346 p. ; 24 cm
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Preface
About the Authors
Summary of Biomimetic Smart Nanoscale Interfacial Materials / Chapter 1:
Definition of Smart Materials / 1.1:
Designing Concept of Bioinspired Smart Interfacial Materials / 1.2:
Typical Examples of Using Above-Mentioned Five Principles to Design Smart Materials / 1.3:
Intellectualizcd Design of Biomimetic Interfacial Materials / 1.4:
References
Living Organisms with Special Surface Performance / Chapter 2:
Self-Cleaning Property of the Surfaces of Plant Leaves / 2.1:
Surface Anisotropy / 2.2:
The Self-Cleaning and Anti-Reflection Functions of the Surfaces of Insect Wings / 2.3:
Walking on Water -- Water Strider / 2.4:
Climbing Up the Wall -- Gecko / 2.5:
A Desert Water-Collecting Insect -- Desert Beetle / 2.6:
Master of Hiding -- Color-Changing Desert Beetle / 2.7:
Structural Color in the Nature / 2.8:
Wettability of the Solid Surface / Chapter 3:
Basic Theory of Wettability / 3.1:
Surfaces with Special Wettability / 3.2:
Contact Angle Hysteresis / 3.3:
Biomimic Superhydrophobic Surface / Chapter 4:
Methods of Preparing Superhydrophobic Surfaces / 4.1:
Multi-functional Superhydrophobic Surfaces / 4.2:
Smart Nanoscale Interfacial Materials with Special Wettability / Chapter 5:
Superamphiphobic Surface / 5.1:
Surface with Superhydrophobicity and Superoleophilicity / 5.2:
Smart Surface with Reversible Superhydrophilicity and Superhydrophobicity / 5.3:
Conclusion and Prospect / Chapter 6:
Super-Lattice Surface Structure (Stable and Metastable Binary Cooperative Complementary Structure) / 6.1:
Optically Controllable Superconducting System (Superconducting/Normal-conducting Phase Binary Cooperative Complimentary Structure) / 6.2:
Chiroptical Switch (Chiral/Achiral Binary Cooperative Complementary Structure) / 6.3:
Novel Mesoporous Structure (Crystalline/Amorphous Phase Binary Cooperative Complementary Structure) / 6.4:
Interface of the Engineered Magnetism (Ferromagnetic/Antiferromagnetic Binary Cooperative Complementary Structure) / 6.5:
Ionic/Nonionic Conductor Binary Cooperative Complementary Structure / 6.6:
Concave/Convex Periodic Binary Cooperative Complementary Structure / 6.7:
Organic/Inorganic Binary Cooperative Complementary Structure / 6.8:
Reference
Index
Preface
About the Authors
Summary of Biomimetic Smart Nanoscale Interfacial Materials / Chapter 1:
9.

図書

図書
edited by Challa S.S.R. Kumar
出版情報: Weinheim : Wiley-VCH, c2010  xix, 431 p. ; 25 cm
シリーズ名: Nanomaterials for the life sciences / edited by Challa S.S.R. Kumar ; v. 5
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Preface
List of Contributors
Polymer Thin Films for Biomedical Applications / Venkat K. Vendra ; Lin Wu ; Sitaraman Krishnan1:
Introduction / 1.1:
Biocompatible Coatings / 1.2:
Protein-Repellant Coatings / 1.2.1:
Pegylated Thin Films / 1.2.1.1:
Non-Pegylated Hydrophilic Thin Films / 1.2.1.2:
Thin Films of Hyperbranched Polymers / 1.2.1.3:
Multilayer Thin Films / 1.2.1.4:
Antithrombogenic Coatings / 1.2.2:
Surface Chemistry and Blood Compatibility / 1.2.2.1:
Membrane-Mimetic Thin Films / 1.2.2.2:
Heparin-Mimetic Thin Films / 1.2.2.3:
Clot-Lyzing Thin Films / 1.2.2.4:
Polyelectrolyte Multilayer Thin Films / 1.2.2.5:
Polyurethane Coatings / 1.2.2.6:
Vapor-Deposited Thin Films / 1.2.2.7:
Antimicrobial Coatings / 1.2.3:
Cationic Polymers / 1.2.3.1:
Nanocomposite Polymer Thin Films Incorporating Inorganic Biocides / 1.2.3.2:
Antibiotic-Conjugated Polymer Thin Films / 1.2.3.3:
Biomimetic Antibacterial Coatings / 1.2.3.4:
Thin Films Resistant to the Adhesion of Viable Bacteria" / 1.2.3.5:
Coatings for Tissue Engineering Substrates / 1.3:
Zwitterionic Thin Films / 1.3.1:
Polysaccharide-Based Thin Films / 1.3.3:
Temperature-Responsive Polymer Coatings / 1.3.6:
Electroactive Thin Films / 1.3.8:
Other Functional Polymer Coatings / 1.3.9:
Multilayer Thin Films for Cell Encapsulation / 1.3.10:
Patterned Thin Films / 1.3.11:
Polymer Thin Films for Drug Delivery / 1.4:
Polymer Thin Films for Gene Delivery / 1.5:
Conclusions / 1.6:
References
Biofunctionalization of Polymeric Thin Films and Surfaces / Holger Schönherr2:
Introduction: The Case of Biofunctionalized Surfaces and Interfaces / 2.1:
Polymer-Based Biointerfaces / 2.2:
Requirements for Biofunctionalized Polymer Surfaces / 2.2.1:
Surface Modification Using Functional Polymers and Polymer-Based Approaches / 2.2.2:
Grafting of Polymers to Surfaces / 2.2.2.1:
Polymer Brushes by Surface-Initiated Polymerization / 2.2.2.2:
Physisorbed Multifunctional Polymers / 2.2.2.3:
Multipotent Covalent Coatings / 2.2.2.4:
Plasma Polymerization and Chemical Vapor Deposition (CVD) Approaches / 2.2.2.5:
Surface Modification of Polymer Surfaces, and Selected Examples / 2.2.3:
Coupling and Bioconjugation Strategies / 2.2.3.1:
Interaction with Cells / 2.2.3.2:
Patterned Polymeric Thin Films in Biosensor Applications / 2.2.3.3:
Summary and Future Perspectives / 2.3:
Stimuli-Responsive Polymer Nanocoatings / Ana L. Cordeiro3:
Stimuli-Responsive Polymers / 3.1:
Polymers Responsive to Temperature / 3.2.1:
Polymers Responsive to pH / 3.2.2:
Dual Responsive/Multiresponsive Polymers / 3.2.3:
Intelligent Bioconjugates / 3.2.4:
Responsive Biopolymers / 3.2.5:
Polymer Films and Interfacial Analysis / 3.3:
Applications / 3.4:
Release Matrices / 3.4.1:
Cell Sheet Engineering / 3.4.2:
Biofilm Control / 3.4.3:
Cell Sorting / 3.4.4:
Stimuli-Modulated Membranes / 3.4.5:
Chromatography / 3.4.6:
Microfluidics and Laboratory-on-a-Chip / 3.4.7:
Acknowledgments / 3.5:
Ceramic Nanocoatings and Their Applications in the Life Sciences / Eng San Thian4:
Magnetron Sputtering / 4.1:
Physical and Chemical Properties of SiHA Coatings / 4.3:
Biological Properties of SiHA Coatings / 4.4:
In Vitro Acellular Testing / 4.4.1:
In Vitro Cellular Testing / 4.4.2:
Future Perspectives / 4.5:
Gold Nanofilrns: Synthesis, Characterization, and Potential Biomedical Applications / Shiho Tokonami ; Hiroshi Shiigi ; Tsutomu Nagaoka4.6:
Preparation of Various AuNPs / 5.1:
Functionalization of AuNPs and their Applications through Aggregation / 5.3:
AuNP Assemblies and Arrays / 5.4:
AuNP Assemblies Structured on Substrates / 5.4.1:
AuNP Assembly on Biotemplates / 5.4.2:
AuNP Arrays for Gas Sensing / 5.4.3:
AuNP Arrays for Biosensing / 5.4.4:
Thin Films on Titania, and Their Applications in the Life Sciences / Izabella Brand ; Martina Nullmeier5.5:
Titanium in Contact with a Biomaterial / 6.1:
Lipid Bilayers at the Titania Surface / 6.3:
Formation of Lipid Bilayers on the Titania Surface / 6.3.1:
Spreading of Vesicles on a TiO2 Surface: Comparison to a SiO2 Surface / 6.3.1.1:
Interactions: lipid Molecule-Titania Surface / 6.3.2:
Structure and Conformation of lipid Molecules in the Bilayer on the Titania Surface / 6.3.3:
Structure of Phosphatidylcholine on the Titania Surface / 6.3.3.1:
Characteristics of Extracellular Matrix Proteins on the Titania Surface / 6.4:
Collagen Adsorption on Titania Surfaces / 6.4.1:
Morphology of Collagen Adsorbed on an Oxidized Titanium Surface / 6.4.1.1:
Adsorption of Collagen on a Hydroxylated Titania Surface / 6.4.1.2:
Morphology and Structure of Collagen Adsorbed on a Calcified Titania Surface / 6.4.1.3:
Structure of Collagen on the Titania Surface: Theoretical Predictions / 6.4.1.4:
Fibronectin Adsorption on the Titania Surface / 6.4.2:
Morphology of Fibronectin Adsorbed on the Titania Surface / 6.4.2.1:
Fibronectin-Titania Interactions / 6.4.2.2:
Structure of Fibronectin Adsorbed onto the Titania Surface / 6.4.2.3:
Atomic-Scale Picture of Fibronectin Adsorbed on the Titania Surface: Theoretical Predictions / 6.4.2.4:
Preparation, Characterization, and Potential Biomedical Applications of Nanostructured Zirconia Coatings and Films / Xuanyong Liu ; Ying Xu ; Paul K. Chu6.4.2.5:
Preparation and Characterization of Nano-ZrO2 Films / 7.1:
Cathodic Arc Plasma Deposition / 7.2.1:
Plasma Spraying / 7.2.2:
Sol-Gel Methods / 7.2.3:
Electrochemical Deposition / 7.2.4:
Anodic Oxidation and Micro-Arc Oxidation / 7.2.5:
Bioactivity of Nano-ZrO2 Coatings and Films / 7.2.6:
Cell Behavior on Nano-ZrO2 Coatings and Films / 7.4:
Applications of Nano-ZrO2 Films to Biosensors / 7.5:
Free-Standing Nanostructured Thin Films / Izumi Ichinose8:
The Roles of Free-Standing Thin Films / 8.1:
Films as Partitions / 8.2.1:
Nanoseparation Membranes / 8.2.2:
Biomembranes / 8.2.3:
Free-Standing Thin Films with Bilayer Structures / 8.3:
Supported Lipid Bilayers and "Black Lipid Membranes" / 8.3.1:
Foam Films and Newton Black Films / 8.3.2:
Dried Foam Film / 8.3.3:
Foam Films of Ionic Liquids / 8-3.4:
Free-Standing Thin Films Prepared with Solid Surfaces / 8.4:
Free-Standing Thin Films of Nanoparticles / 8.5:
Nanofibrous Free-Standing Thin Films / 8.6:
Electrospinning and Filtration Methods / 8.6.1:
Metal Hydroxide Nanostrands / 8.6.2:
Nanofibrous Composite Films / 8:6.3:
Dip-Pen Nanolithography of Nanostructured Thin Films for the Life Sciences / Euiseok Kim ; Yuan-Shin Lee ; Ravi Aggarwal ; Roger J. Narayan8.6.4:
Dip-Pen Nanolithography / 9.1:
Important Parameters / 9.2.1:
Applications of DPN / 9.2.2:
Direct and Indirect Patterning of Biomaterials Using DPN / 9.3:
Background / 9.3.1:
Direct Patterning / 9.3.2:
Indirect Patterning / 9.3.3:
Applications of DPN for Medical Diagnostics and Drug Development / 9.4:
General Methods of Nano/Micro Bioarray Patterning / 9.4.1:
Virus Array Generation and Detection Tests / 9.4.2:
Diagnosis of Allergic Disease / 9.4.3:
Cancer Detection Using Nano/Micro Protein Arrays / 9.4.4:
Drug Development / 9.4.5:
Lab-on-a-Chip Using Microarrays / 9.4.6:
Summary and Future Directions / 9.5:
Understanding and Controlling Wetting Phenomena at the Micro-and Nanoscales / Zuankai Wang ; Nikhil Koratkar10:
Wetting and Contact Angle / 10.1:
Design and Creation of Superhydrophobic Surfaces / 10.3:
Design Parameters for a Robust Composite Interface / 10.3.1:
Creation of Superhydrophobic Surfaces / 10.3.2:
Superhydrophobic Surfaces with Unitary Roughness / 10.3.3:
Superhydrophobic Surfaces with Two-Scale Roughness / 10.3.4:
Superhydrophobic Surfaces with Reentrant Structure / 10.3.5:
Impact Dynamics of Water on Superhydrophobic Surfaces / 10.4:
Impact Dynamics on Nanostructured MWNT Surfaces / 10.4.1:
Impact Dynamics on Micropattemed Surfaces / 10.4.2:
Electrically Controlled Wettability Switching on Superhydrophobic Surfaces / 10.5:
Reversible Control of Wettability Using Electrostatic Methods / 10.5.1:
Electrowetting on Superhydrophobic Surfaces / 10.5.2:
Novel Strategies for Reversible Electrowetting on Rough Surfaces / 10.5.3:
Electrochemically Controlled Wetting of Superhydrophobic Surfaces / 10.6:
Polarity-Dependent Wetting of Nanotube Membranes / 10.6.1:
Mechanism of Polarity-Dependent Wetting and Transport / 10.6.2:
Potential Applications of Electrochemically Controlled Wetting and Transport / 10.6.3:
Imaging of Thin Films, and Its Application in the Life Sciences / Silvia Mittler10.7:
Thin Film Preparation Methods / 11.1:
Dip-Coating / 11.2.1:
Spin-Coating / 11.2.2:
Langmuir-Blodgett (LB) Films
Self-Assembled Monolayers / 11.2.4:
Layer-by-Layer Assembly / 11.2.5:
Polymer Brushes: The "Grafting-From" Approach / 11.2.6:
Structuring: The Micro- and Nanostructuring of Thin Films / 11.3:
Photolithography / 11.3.1:
Ion Lithography and FIB Lithography / 11.3.2:
Electron lithography / 11.3.3:
Micro-Contact Printing and Nanoimprinting (NIL) / 11.3.4:
Near-Field Scanning Methods / 11.3.5:
Other Methods / 11.3.6:
Imaging Technologies / 11.4:
The Concept of Total Internal Reflection / 11.4.1:
The Concept of Waveguiding / 11.4.2:
Brewster Angle Microscopy (BAM) / 11.4.3:
Resonant Evanescent Methods / 11.4.4:
Surface Plasmon Resonance Microscopy / 11.4.4.1:
Waveguide Resonance Microscopy / 11.4.4.2:
Surface Plasmon Enhanced Fluorescence Microscopy / 11.4.4.3:
Waveguide Resonance Microscopy with Electro-Optical Response / 11.4.4.4:
Nonresonant Evanescent Methods / 11.4.5:
Total Internal Reflection Fluorescence (TIRF) Microscopy / 11.4.5.1:
Waveguide Scattering Microscopy / 11.4.5.2:
Waveguide Evanescent Field Fluorescence Microscopy (WEFFM) / 11.4.5.3:
Confocal Raman Microscopy and One- and Two-Photon Fluorescence Confocal Microscopy / 11.4.5.4:
Application of Thin Films in the Life Sciences / 11.5:
Sensors / 11.5.1:
Surface Functionalization for Biocompatibility / 11.5.2:
Drug Delivery / 11.5.3:
Bioreactors / 11.5.4:
Cell-Surface Mimicking / 11.5.5:
Summary / 11.6:
Structural Characterization Techniques of Molecular Aggregates, Polymer, and Nanoparticle Films / Takeshi Hasegawa12:
Characterization of Ultrathin Films of Soft Materials / 12.1:
X-Ray Diffraction Analysis / 12.2.1:
Infrared Transmission and Reflection Spectroscopy / 12.2.2:
Multiple-Angle Incidence Resolution Spectrometry (MAIRS) / 12.2.3:
Theoretical Background of MAIRS / 12.2.3.1:
Molecular Orientation Analysis in Polymer Thin Films by IR-MAIRS / 12.2.3.2:
Analysis of Metal Thin Films / 12.2.3.3:
Index
Preface
List of Contributors
Polymer Thin Films for Biomedical Applications / Venkat K. Vendra ; Lin Wu ; Sitaraman Krishnan1:
10.

図書

図書
edited by Ali Eftekhari
出版情報: West Sussex, U.K. : Wiley, 2010  xxiii, 776 p., [4]leaves of plates ; 26 cm
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Preface
Foreword
List of Contributors
History of Conductive Polymers / J. Campbell ScottPart 1:
Introduction / 1.1:
Archeology and prehistory / 1.2:
The dawn of the modern era / 1.3:
The materials revolution / 1.4:
Concluding remarks / 1.5:
Acknowledgments
References
Polyaniline nanostructures / Gordana Ciric-Marjanovic2:
Preparation / 2.1:
Structure and Properties / 2.3:
Processing and Applications / 2.4:
Conclusions and Outlook / 2.5:
Nanoscale Inhomogeneity of Conducting Polymer Based Materials / Alain Pailleret ; Oleg Semenikhin3:
Introduction: Inhomogeneity and Nanostructured Materials / 3.1:
Direct Local Measurements of Nanoscale Inhomogeneity of Conducting and Semiconducting Polymers / 3.2:
In-situ Studies of Conducting and Semiconducting Polymers: / 3.3:
The Origin of the Nanoscale Inhomogeneity of Conducting and Semiconducting Polymers / 3.4:
Nanostructured Conductive Polymers by Electrospinning / Ioannis S. ChronakisPart 2:
Introduction to Electrospinning Technology / 4.1:
Electrospinning Processing / 4.2:
Electrospinning Processing Parameters - Control of the Nanofiber Morphology / 4.3:
Nanostructured conductive polymers by electrospinning / 4.4:
Application of Electrospun Nanostructrured Conductive Polymers / 4.5:
Composites based on conducting polymers and carbon nanotubes / M.Baibarac ; I.Baltog ; S. Lefrant5:
Carbon Nanotubes / 5.1:
Synthesis of composites based on conducting polymers and carbon nanotubes / 5.3:
Vibrational properties of composites based on conducting polymers and carbon nanotubes / 5.4:
Conclusions / 5.5:
Inorganic-Based Nanocomposites of Conductive Polymers / Rabin Bissessur6:
FeOCl / 6.1:
Layered phosphates and phosphonates / 6.3:
Layered Rutiles / 6.7:
Layered perovskites / 6.8:
Layered Titanates / 6.9:
Graphite Oxide / 6.10:
Acknowledgements / 6.11:
Metallic-based Nanocomposites of Conductive Polymers / Vessela Tsakova7:
Oxidative Polymerization Combined with Metal Ions Reduction (One-pot Synthesis) / 7.1:
Nanocomposite Formation by Means of Pre-synthesized Metal Nanoparticles / 7.3:
Metal Electrodeposition in Pre-synthesized CPs / 7.4:
Chemical Reduction of Metal Ions in Pre-polymerized CP Suspensions or Layers / 7.5:
Metallic Based Conducting Polymer Composites for Electrocatalytic and Electroanalytic Applications / 7.6:
List of Acronyms
Spectroscopy of Nanostructured Conducting Polymers / Gustavo M. do Nascimento ; Marcelo A. de Souza8:
Synthetic Metals / 8.1:
Nanostructured Conducting Polymers / 8.2:
Spectroscopic Techniques / 8.3:
Concluding Remarks / 8.4:
Atomic Force Microscopy Study of Conductive Polymers / Edgar Ap. Sanches ; Osvaldo N. Oliveira Jr ; Fabio de Lima Leite9:
AFM Fundamentals and Applications / 9.1:
Single Conducting Polymer Nanowires / Yixuan Chen ; Yi Luo9.3:
Fabrication of Single Conducting Polymer Nanowires (CPNWs) / 10.1:
Transport Properties and Electrical Characterization / 10.3:
Application of Single Conducting Polymer Nanowires (CPNWs) / 10.4:
Summary and Outlook / 10.5:
Conductive Polymer Micro and Nano Containers / Jiyong Huang ; Zhixiang Wei11:
Structures of Micro- and Nano- Containers / 11.1:
Preparation Method and Formation Mechanism / 11.2:
Properties and Applications of Micro- and Nano- Containers / 11.3:
Magnetic and Electron Transport Behaviors of Conductive Polymer Nanocomposites / Zhanhu Guo ; Suying Wei ; David Cocke ; Di Zhang11.4:
Magnetic Polymer Nanocomposite Preparation / 12.1:
Physicochemical Property Characterization / 12.3:
Microstructure of the Conductive Polymer Nanocomposites / 12.4:
Interaction between the Nanoparticles and Conductive Polymer Matrix / 12.5:
Magnetic Properties of Conductive Polymer Nanocomposites / 12.6:
Electron Transport in Conductive Polymer Nanocomposites / 12.7:
Giant Magnetoresistance in Conductive Polymer Nanocomposites / 12.8:
Summary / 12.9:
Charge Transfer and Charge Separation in Conjugated Polymer Solar Cells / Ian A. Howard ; Neil C. Greenham ; Agnese Abrusci ; Richard H. Friend ; Sebastian Westenhoff13:
Charge Transfer in Conjugated Polymers / 13.1:
Charge Generation and Recombination in Organic Solar Cells with High Open-Circuit Voltage / 13.3:
Nanostructured conducting polymers for (electro)chemical sensors / Anthony J. Killard13.4:
Nanowires and Nanotubes / 14.1:
Nanogaps and nanojunctions / 14.3:
Nanofibres and nanocables / 14.4:
Nanofilms / 14.5:
Metallic nanoparticle/conducting polymer nanocomposites / 14.6:
Metal oxide nanoparticles/conducting polymer nanocomposites / 14.7:
Carbon Nanotube nanocomposites / 14.8:
Nanoparticles / 14.9:
Nanoporous templates / 14.10:
Application summaries / 14.11:
Nanostructural Aspects of Conducting Polymer Actuators / Paul A. Kilmartin ; Jadranka Travas-Sejdic14.12:
Mechanism and modes of actuation / 15.1:
Modelling mechanical performance and developing device applications / 15.3:
Effect of morphology and nanostructure upon actuation / 15.4:
Solvent and ion size effects to achieve higher actuation / 15.5:
Nanostructured composite actuators / 15.6:
Prospects for nanostructured conducting polymer actuators / 15.7:
Electroactive Conducting Polymers for the Protection of Metals against Corrosion: from Micro- to Nanostructured Films / Pierre Camille Lacaze ; Jalal Ghilane ; Hyacinthe Randriamahazaka ; Jean-Christophe Lacroix16:
Protection Mechanisms Induced by Conducting Polymers / 16.1:
Conducting Polymer Coating Techniques for Usual Oxidizable Metals and Performances of Conducting Polymer-Based Micron-Thick Films for Protection against Corrosion / 16.3:
Nanostructured Conducting Polymer Coatings and Anticorrosion Protection / 16.4:
Acknowledgement / 16.5:
Electrocatalysis by Nanostructured Conducting Polymers / Shaolin Mu ; Ya Zhang17:
Electrochemical synthetic techniques of nanostructured conducting polymers / 17.1:
Electrocatalysis at nanostructured conducting polymer electrodes / 17.3:
Conclusion / 17.4:
Nanostructured Conductive Polymers as Biomaterials / Rylie A. Green ; Sungchul Baek ; Nigel H. Lovell ; Laura A. Poole-Warren18:
Biomedical applications for conductive polymers / 18.1:
Polymer design considerations / 18.3:
Fabrication of nanostructured conductive polymers / 18.4:
Polymer characterisation / 18.5:
Interfacing with neural tissue / 18.6:
Nanocomposites of Polymers Made Conductive by Nanofillers / Haiping Hong ; Dustin Thomas ; Mark Horton ; Yijiang Lu ; Jing Li ; Pauline Smith ; Walter Roy18.7:
Experimental / 19.1:
Results and discussion / 19.3:
Index / 19.4:
Preface
Foreword
List of Contributors
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