The second part emphasizes the techniques used for characterizing the structure and properties of nanomaterials, aiming at describing the physical mechanism, data interpretation, and detailed applications of the techniques. 本书内容强调纳米材料的合成, 详细介绍了常用的化学和物理纳米合成方法的原理和基本程序, 并介绍了各种方法的最新进展和参考文献

zlibzh/no-category/王中林主编, edited by Zhong Lin Wang, Yi Liu, and Ze Zhang, Zhong Lin Wang, Yi Liu, Ze Zhang, Zhong Lin Wang, Ze Zhang, Yi Liu, 王中林主编, 王中林/Handbook of Nanophase and Nanostructured Materials——Synthesis_29574602.pdf

纳米相和纳米结构材料--合成手册 : [英文版] Na mi xiang he na mi jie gou cai liao -- he cheng shou ce : [ Ying wen ban

Handbook of Nanophase and Nanostructured Materials Vol. 4 : Materials Systems and Applications II

Handbook Of Nanophase And Nanostructured Materials Vol. 3 : Materials Systems And Applications I

Handbook of nanophase and nanostructured materials. Vol. 2, Characterization

Handbook Of Nanophase And Nanostructured Materials Vol. 1 : Synthesis

Handbook of nanophase and nanostructured materials. Vol. 3, Synthesis

Handbook of nanophase and nanostructured materials = 纳米相和纳米结构材料 (II)

纳米相和纳米结构材料应用 2 手册 英文版

纳米相和纳米结构材料——结构和性能表征手册

纳米相和纳米结构材料应用(II)手册

Wang, Zhong Lin., Liu, Yi, Zhang, Ze

王中林,刘义,张泽主编

Kluwer Academic / Plenum Publishers ; Tsinghua University Press

清华大学出版社 Qing hua da xue chu ban she

Springer Science & Business Media

Da Capo Press, Incorporated

Qinghua University Press

Hachette Books

Hachette GO

Springer Nature (Textbooks & Major Reference Works), New York, 2003

21 Shi ji ke ji qian yan cong shu, Di 1 ban, 北京 Beijing, 2002

SpringerLINK ebook collection, New York, ©2003

New York, New York State, October 1, 2002

United States, United States of America

Springer Nature, [Boston?], 2003

China, People's Republic, China

1 edition, October 1, 2002

1 edition, August 1, 2002

New York, [Beijing, 2003

New York; London, 2003

Boston, MA, 2003

1, 2003

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Includes bibliographical references and indexes.

Bookmarks: p1 (p1): 10 Nanomechanism of the Hexagonal-Cubic Phase Transition in Boron Nitride under High Pressure at High Temperature
p1-2 (p1): 10.1 Introduction
p1-3 (p2): 10.2 Processing Method to Get c-BN
p1-4 (p3): 10.3 Characterization Method
p1-5 (p4): 10.4 Phase Transition of Boron Nitride
p1-6 (p4): 10.4.1 Nanostructure of the Starting Material
p1-7 (p6): 10.4.2 Phases and Nanostructures Appearing during the Hexagonal-Cubic Transition
p1-8 (p16): 10.5 Mechanism of Hexagonal-Cubic Transition
p1-9 (p16): 10.5.1 Model for the Transition Mechanism
p1-10 (p19): 10.5.3 Facilitation of Synthesis of c-BN by Mechanochemical Effect
p1-11 (p19): 10.5.2 Atomic Movement during the Conversion from w-to c-BN
p1-12 (p22): 10.6 Prospect
p1-13 (p22): 10.7 Conclusions
p1-14 (p24): References
p2 (p26): 11 Nanomaterials for Energy Storage:Batteries and Fuel Cells
p2-2 (p26): 11.1 General Overview of Batteries and Fuel Cells
p2-3 (p26): 11.1.1 Introduction
p2-4 (p27): 11.1.2 An Overview of Batteries
p2-5 (p29): 11.1.3 An Overview of Fuel Cells
p2-6 (p33): 11.1.4 Importance of Nanomaterials in Batteries and Fuel Cells
p2-7 (p34): 11.2 Batteries and Nanomaterials
p2-8 (p34): 11.2.1 Classifications of Advanced Batteries
p2-9 (p37): 11.2.2 Major Components of Batteries
p2-10 (p39): 11.2.3 Applications of Nanomaterials in Advanced Batteries
p2-11 (p46): 11.2.4 Most Recent Developments
p2-12 (p46): 11.3 Fuel Cells and Nanomaterials
p2-13 (p46): 11.3.1 Classifications of Fuel Cell Systems
p2-14 (p49): 11.3.2 Major Components and Nanomaterials in Fuel Cells
p2-15 (p50): 11.3.3 Applications of Nanomaterials in Fuel Cells
p2-16 (p60): 11.3.4 Summary
p2-17 (p60): 11.4 Conclusions
p2-18 (p61): References
p2-19 (p69): 12.1 Introduction
p3 (p69): 12 Nanocomposites
p3-2 (p74): 12.2 General Features of Nanocomposites
p3-3 (p74): 12.2.1 Physical Sensitivity:Three Effects of Nanoparticles on Material Properties
p3-4 (p75): 12.2.2 Chemical Reactivity
p3-5 (p76): 12.2.3 Promising Improvements in Nanocomposites
p3-6 (p77): 12.2.4 Origin of Nanophases and Generating Stages
p3-7 (p79): 12.3 Ceramic-Based Nanocomposites
p3-8 (p80): 12.3.1 Strength Improvement of Ceramic-Based Nanocomposites
p3-9 (p84): 12.3.2 Toughening Effect of Nanoceramic Composites
p3-10 (p86): 12.3.3 Improvements of Nanoceramic Composites on Hardness and Wear
p3-11 (p86): 12.3.4 Superplasticity of Ceramic Nanocomposites
p3-12 (p88): 12.3.5 Improvement of Nanoceramic Composites on Creep
p3-13 (p89): 12.4 Metallic-Based Nanocomposites
p3-14 (p89): 12.3.6 Ceramic-Based Nanometallic Composites
p3-15 (p91): 12.5 Polymer-Based Nanocomposites
p3-16 (p93): 12.6 Summaries of Nanocomposites
p3-17 (p94): References
p4 (p96): 13 Growth and Properties of Single-Walled Carbon Nanotubes
p4-2 (p96): 13.1 Introduction
p4-3 (p97): 13.2 Synthetic Strategies for Various Nanotube Architectures
p4-4 (p97): 13.2.1 Chemical Vapor Deposition
p4-5 (p99): 13.2.2 Growth of Self-oriented Multi-Walled Nanotubes
p4-6 (p100): 13.2.3 Enable the Growth of Single-Walled Nanotubes by CVD
p4-7 (p102): 13.2.5 Growth of lsolated Single-Walled Nanotubes on Controlled Surface Sites
p4-8 (p102): 13.2.4 Growth Mechanism of SWNT
p4-9 (p104): 13.2.6 Growth of Suspended SWNTs With Directed Orientations
p4-10 (p106): 13.3 Physics in Atomically Well-Defined Nanowires
p4-11 (p106): 13.3.1 Integrated Circuits of Individual Single-Walled Nanotubes
p4-12 (p107): 13.3.2 Electron Transport Properties of Metallic Nanotubes
p4-13 (p110): 13.3.3 Electron Transport Properties of Semiconducting Nanotubes
p4-14 (p114): 13.3.4 Electron Transport Properties of Semiconducting Nanotubes with Small Band Gaps
p4-15 (p121): 13.4 Integrated Nanotube Devices
p4-16 (p121): 13.4.1 Nanotube Molecular Transistors With High Gains
p4-17 (p123): 13.5 Conclusions
p4-18 (p125): References
p4-19 (p128): 14.2 Theoretical Prediction
p4-20 (p128): 14.1 Introduction
p5 (p128): 14 Nanomaterials from Light-Element Composites
p5-2 (p129): 14.2.1 Empirical Model
p5-3 (p130): 14.2.2 First-Principles Study
p5-4 (p131): 14.3 Synthesis by Chemical Vapor Deposition(CVD)
p5-5 (p132): 14.3.1 Bias-Assisted Hot Filament CVD
p5-6 (p133): 14.3.2 Electron Cyclotron Resonance Microwave Plasma-Assisted CVD(MPCVD)
p5-7 (p134): 14.4 Uniform Size-Controlled Nanocrystalline Diamond Films
p5-8 (p135): 14.4.1 Deposition with CN4/N2 Precursor
p5-9 (p139): 14.4.2 Influence of Additional H2 on Microstructure
p5-10 (p141): 14.4.3 Nitrogen Incorporation
p5-11 (p141): 14.4.4 Surface Stable Growth Model
p5-12 (p142): 14.4.5 Field Electron Emission and Transport Tunneling Mechanism
p5-13 (p144): 14.5 Nanocrystalline Carbon Nitride Films
p5-14 (p145): 14.5.1 αandβStructures
p5-15 (p146): 14.5.2 Tetragonal Structure
p5-16 (p147): 14.5.3 Monoclinic Structure
p5-17 (p147): 14.5.4 Fullerene-like Structure
p5-18 (p148): 14.5.5 Carbon Nitride Diamond Silicon Layers
p5-19 (p149): 14.5.6 Physical and Chemical Properties
p5-20 (p150): 14.6 Nanocrystalline Silicon Carbonitride Films
p5-21 (p151): 14.6.1 Deposition With Nitrogen and Methane
p5-22 (p154): 14.6.2 Deposition with Nitrogen.Methane and Hydrogen:Influence of Hydrogen Flow Ratio
p5-23 (p155): 14.6.3 Lattice-Matched Growth Model
p5-24 (p156): 14.7.1 Morphology and Composition
p5-25 (p156): 14.7 Turbostratic Boron Carbonitride Films
p5-26 (p157): 14.7.2 Turbostratic Structure
p5-27 (p159): 14.7.3 Raman and Photoluminescence
p5-28 (p160): 14.7.4 Field Electron Emission
p5-29 (p161): 14.8 Polymerized Nitrogen-Incorporated Carbon Nanobells
p5-30 (p161): 14.8.1 Polymerized Nanobell Structure
p5-31 (p163): 14.8.2 Chemical Separation and Application
p5-32 (p164): 14.8.3 Wall-Side Field Emission Mechanism
p5-33 (p165): 14.9 Highly Oriented Boron Carbonitride Nanofibers
p5-34 (p165): 14.9.1 Microstructure and Composition
p5-35 (p167): 14.10 Conclusions
p5-36 (p167): 14.9.2 Field Electron Emission
p5-37 (p169): References
p6 (p174): 15 Self-Assembled Ordered Nanostructures
p6-2 (p174): 15.1 Ordered Self-Assembled Nanocrystals
p6-3 (p177): 15.1.1 Processing of Nanocrystals for Self-Assembly
p6-4 (p182): 15.1.2 Technical Aspects of Self-Assembling
p6-5 (p185): 15.1.3 Structure of the Nanocrystal Self-Assembly
p6-6 (p190): 15.1.4 Properties of the Nanocrystal Self-Assembly
p6-7 (p195): 15.2 Ordered Self-Assembly of Mesoporous Materials
p6-8 (p196): 15.2.1 Processing
p6-9 (p197): 15.2.2 The Formation Mechanisms
p6-10 (p199): 15.2.3 Applications
p6-11 (p203): 15.2.4 Mesoporous Materials of Transition Metal Oxides
p6-12 (p205): 15.3 Hierarchically Structured Nanomaterials
p6-13 (p207): 15.4 Summary
p6-14 (p207): References
p7 (p211): 16 Molecularly Organized Nanostructural Materials
p7-2 (p211): 16.1 Introduction
p7-3 (p211): 16.1.1 Nanostructural Materials in Energy Sciences
p7-4 (p212): 16.1.2 Nanophase Materials in Environmental and Health Sciences
p7-5 (p213): 16.1.3 Molecularly Organized Nanostructural Materials
p7-6 (p213): 16.2 Molecularly Directed Nucleation and Growth.and Matrix Mediated Nanocomposites
p7-7 (p213): 16.2.1 Molecularly Directed Nanoscale Materials in Nature
p7-8 (p214): 16.2.2 Directed Nucleation and Growth of Thin Films
p7-9 (p217): 16.2.3 Matrix Mediated Nanocomposites
p7-10 (p221): 16.3 Surfactant Directed Hybrid Nanoscale Materials
p7-11 (p222): 16.3.1 Ordered Nanoporous Materials
p7-12 (p227): 16.3.2 Hybrid Nanoscale Materials
p7-13 (p233): 16.4 Summary and Prospects
p7-14 (p234): References
p8 (p237): 17 Nanostructured Bio-inspired Materials
p8-2 (p237): 17.1 Introduction
p8-3 (p240): 17.2 Case Study Ⅰ:Teeth
p8-4 (p241): 17.2.1 Control over Mineralization at Nanometer Scale
p8-5 (p244): 17.2.2 Hierarchical Structure in Biological Materials
p8-6 (p246): 17.3 Case Study Ⅱ:Mesoscopic Silica Films
p8-7 (p248): 17.3.1 Hierarchical Film Structure
p8-8 (p253): 17.3.2 Towards Control of the Properties
p8-9 (p254): 17.4 Conclusion
p8-10 (p254): References
p9 (p257): 18 Nanophase Metal Oxide Materials for Electrochromic Displays
p9-2 (p257): 18.1 Introduction
p9-3 (p258): 18.2 Basic Concepts in Electrochromism
p9-4 (p258): 18.2.1 Electrochromic Display Device
p9-5 (p260): 18.2.2 Electrochromic Materials
p9-6 (p261): 18.2.3 Perceived Color and Contrast Ratio
p9-7 (p262): 18.2.4 Coloration Efficiency and Response Time
p9-8 (p262): 18.2.5 Write-Erase Efficiency and Cycle Life
p9-9 (p263): 18.3 Nanophase Metal Oxide Electrochromic Materials
p9-10 (p264): 18.3.1 Synthesis of Supported ATO Nanocrystallites
p9-11 (p266): 18.3.2 Characterization of Supported ATO Nanocrystallites
p9-12 (p268): 18.4 Construction of Printed.Flexible Displays Using Interdigitated Electrodes
p9-13 (p268): 18.4.1 Design Strategy
p9-14 (p270): 18.4.2 Materials Selection
p9-15 (p272): 18.4.3 Display Examples
p9-16 (p274): 18.5 Contrast of Printed Electrochromic Displays Using ATO Nanophase Materials
p9-17 (p275): 18.5.1 Effect of Antimony Doping on Contrast Ratio
p9-18 (p281): 18.5.2 Effect of Annealing Temperature on Contrast Ratio
p9-19 (p285): 18.5.3 Other Factors That Affect the Contrast Ratio
p9-20 (p289): References
p9-21 (p289): 18.6 Summary
p10 (p292): 19 Engineered Microstructures for Nonlinear Optics
p10-2 (p292): 19.1 Introduction
p10-3 (p293): 19.2 Preparation of DSLs
p10-4 (p293): 19.2.1 Preparation of DSLs by Modulation of Ferroelectric Domains
p10-5 (p296): 19.2.2 Preparation of DSL by Using Photorefractive Effect
p10-6 (p297): 19.3 Outline of the Nonlinear Optics
p10-7 (p298): 19.4 Wave Vector Conservation
p10-8 (p301): 19.5 Nonlinear Optical Frequency Conversion in 1-D Periodic DSLs
p10-9 (p303): 19.6 Nonlinear Optical Frequency Conversion in 1-D QPDSLs
p10-10 (p304): 19.6.1 The Construction of QPDSL
p10-11 (p305): 19.6.2 Theoretical Treatment of the Nonlinear Optical Processes in QPDSLs
p10-12 (p309): 19.6.3 The Effective Nonlinear Optical Coefficients
p10-13 (p309): 19.6.4 QPM Multiwavelength SHG
p10-14 (p310): 19.6.5 Direct THG
p10-15 (p311): 19.7 Optical Bistability in a 2-D DSL
p10-16 (p312): 19.7.1 Bloch Wave Approach
p10-17 (p315): 19.7.2 Four-Path Switch:Linear Case
p10-18 (p316): 19.7.3 A New Type of Optical Bistability Mechanism:Nonlinear Case with One Incident Wave
p10-19 (p319): 19.7.4 A New Type of Optical Bistability Mechanism:Nonlinear Case With Two Incident Waves
p10-20 (p320): 19.8 Outlook
p10-21 (p322): References
p10-22 (p329): Index

Bookmarks: p1 (p1): 1 X-ray and Neutron Scattering
p1-2 (p1): 1.1 Introduction
p1-3 (p4): 1.2 X-ray and Neutron Diffraction
p1-4 (p14): 1.3 Inelastic Neutron Scattering
p1-5 (p21): 1.4 Small Angle Scattering
p1-6 (p24): 1.5 Concluding Remarks
p1-7 (p25): References
p2 (p29): 2 Transmission Electron Microscopy and Spectroscopy
p2-2 (p29): 2.1 Major Components of a Transmission Electron Microscope
p2-3 (p31): 2.2 Atomic Resolution Lattice Imaging of Crystalline Specimens
p2-4 (p31): 2.2.1 Phase Contrast
p2-5 (p32): 2.2.2 Abbe’s Imaging Theory
p2-6 (p34): 2.2.3 Image Interpretation of Very Thin Samples
p2-7 (p34): 2.2.4 Image Simulation
p2-8 (p37): 2.3 Faceted Shapes of Nanocrystals
p2-9 (p37): 2.3.1 Polyhedral Shapes of Nanoparticles
p2-10 (p41): 2.3.2 Twinning Structure and Stacking Faults
p2-11 (p42): 2.3.3 Decahedral and lcosahedral Particles
p2-12 (p43): 2.3.4 Nucleation and Growth of Nanoparticles
p2-13 (p46): 2.4 Electron Holography
p2-14 (p48): 2.5 Lorentz Microscopy
p2-15 (p48): 2.5.1 Principle of Lorentz Microscopy
p2-16 (p49): 2.5.3 Fresnel Lorentz Microscopy
p2-17 (p49): 2.5.2 Elimination/Reduction of Magnetic Field from Objective Lens
p2-18 (p50): 2.5.4 Foucault Lorentz Microscopy
p2-19 (p51): 2.5.5 Differential Phase Contrast Mode of Lorentz Microscopy in STEM
p2-20 (p52): 2.6 Nanodiffraction
p2-21 (p53): 2.6.1 Optics for Nanodiffraction
p2-22 (p53): 2.6.2 Experimental Procedures to Obtain a Nanodiffraction Pattern
p2-23 (p54): 2.6.3 Some Applications
p2-24 (p61): 2.7 In situ TEM and Nanomeasurements
p2-25 (p62): 2.7.1 Thermodynamic Properties of Nanocrystals
p2-26 (p68): 2.7.2 Nanomeasurement of Electrical Transport in Quantum Wires
p2-27 (p70): 2.7.3 Nanomeasurement of Mechanical Properties of Fiber-Like Structures
p2-28 (p71): 2.7.4 Femtogram Nanobalance of a Single Fine Particle
p2-29 (p72): 2.7.5 Electron Field Emission from a Single Carbon Nanotube
p2-30 (p75): 2.8 Electron Energy Loss Spectroscopy of Nanoparticles
p2-31 (p75): 2.8.1 Valence Excitation Spectroscopy
p2-32 (p77): 2.8.2 Quantitative Nanoanalysis
p2-33 (p79): 2.8.3 Near Edge Fine Structure and Bonding in Transition Metal Oxides
p2-34 (p81): 2.8.4 Doping of Light Elements in Nanostructures
p2-35 (p85): 2.9 Energy-Filtered Electron Imaging
p2-36 (p85): 2.9.1 Chemical Imaging of Giant Magnetoresistive Multilayers
p2-37 (p89): 2.9.2 Imaging of Spin Valves
p2-38 (p91): 2.9.3 Mapping Valence States of Transition Metals
p2-39 (p93): 2.10 Energy Dispersive X-ray Microanalysis(EDS)
p2-40 (p94): 2.11 Summary
p2-41 (p95): References
p3 (p99): 3 Scanning Electron Microscopy
p3-2 (p99): 3.1 Introduction
p3-3 (p100): 3.2 Basic Principals of Scanning Electron Microscopy
p3-4 (p101): 3.2.1 Main Parameters of Electron Optics
p3-5 (p102): 3.2.2 The Minimum Attainable Beam Diameter
p3-6 (p103): 3.3 Contrast Formation and Interpretation
p3-7 (p111): 3.4 Secondary Electron Detectors
p3-8 (p111): 3.4.1 Everhart-Thornley Detector
p3-9 (p112): 3.4.2 In-iens Secondary Electron Detector
p3-10 (p114): 3.5 Dedicated Detectors
p3-11 (p114): 3.5.1 Solid-State Diode Detector
p3-12 (p115): 3.5.2 Scintillator Backscattered Electron Detector
p3-13 (p115): 3.5.3 BSE-to-SE Conversion Detectors
p3-14 (p115): 3.5.4 Multi-detector System
p3-15 (p116): 3.5.5 Electron Backscattered Diffraction(EBSD)
p3-16 (p117): 3.5.6 Magnetic Contrast
p3-17 (p118): 3.5.7 X-ray Spectrometers
p3-18 (p120): 3.6 Conclusions
p3-19 (p121): References
p3-20 (p124): 4.1 Overview
p4 (p124): 4 Scanning Probe Microscopy
p4-2 (p125): 4.2 Scanning Tunneling Microscopy
p4-3 (p125): 4.2.1 Introduction
p4-4 (p127): 4.2.2 STM Studies on Metals
p4-5 (p130): 4.2.3 STM Studies on Semiconducting Surfaces
p4-6 (p135): 4.2.4 Organic Molecules Studied by STM
p4-7 (p138): 4.3 Atomic Force Microscopy
p4-8 (p138): 4.3.1 Introduction
p4-9 (p139): 4.3.2 The Force Sensor
p4-10 (p141): 4.3.3 lllustration of AFM Applications
p4-11 (p144): 4.3.4 Force Spectrum Analysis
p4-12 (p146): 4.3.5 Lateral Force Microscopy
p4-13 (p147): 4.3.6 Force Microscope operating in Non-contact Mode
p4-14 (p148): 4.3.7 Force Microscope Operating in Tapping Mode
p4-15 (p150): 4.3.8 Magnetic Force Microscopy
p4-16 (p152): 4.4 Ballistic-Electron-Emission Microscopy
p4-17 (p152): 4.4.1 The Principle of BEEM
p4-18 (p154): 4.4.2 BEEM Experiments
p4-19 (p156): 4.4.3 Ballistic-Hole Spectroscopy of Interfaces
p4-20 (p159): 4.5 Applications of STM and BEEM in Surface and Interface Modifications
p4-21 (p160): 4.5.1 Surface Nanofabrication with STM
p4-22 (p164): 4.5.2 Single Atom Manipulation
p4-23 (p166): 4.5.3 Interfacial Modification with BEEM
p4-24 (p167): 4.6 Concluding Remarks
p4-25 (p168): References
p5 (p172): 5 Optical Spectroscopy
p5-2 (p172): 5.1 Introduction
p5-3 (p173): 5.2 Nanoclusters and Nanocrystals
p5-4 (p174): 5.2.1 Absorption and Photoluminescence Spectroscopic Evidence for Quantum Confinement
p5-5 (p181): 5.2.2 Raman and FTIR Studies on the QDs and Its Supramolecular Assemblies
p5-6 (p184): 5.2.3 High Resolution Spectroscopy of Individual Quantum Dots
p5-7 (p192): 5.2.4 Ultrafast Spectroscopy in Quantum Confined Structures
p5-8 (p197): 5.3.1 Processing on the Nanostructures
p5-9 (p197): 5.3 The Control of Nanostructures by Spectroscopic Diagnosis
p5-10 (p201): 5.3.2 Spectroscopic Diagnosis
p5-11 (p212): 5.3.3 Photovoltage Spectroscopy of Surface and Interface
p5-12 (p215): References
p6 (p219): 6 Dynamic Properties of Nanoparticles
p6-2 (p219): 6.1 Introduction
p6-3 (p220): 6.2 Experimental Techniques
p6-4 (p220): 6.2.1 Synthesis of Semiconductor Nanoparticles
p6-5 (p222): 6.2.2 Synthesis of Metal Nanoparticles
p6-6 (p222): 6.2.3 Characterization of Nanoparticles
p6-7 (p223): 6.2.4 Dynamics Measurements with Time-Resolved Techniques
p6-8 (p225): 6.3.1 Theoretical Considerations
p6-9 (p225): 6.3 Dynamic Properties of Semiconductor Nanoparticles
p6-10 (p228): 6.3.2 CdS,CdSe and Related Systems
p6-11 (p231): 6.3.3 Metal Oxide Nanoparticles:TiO2,Fe2O3,ZnO,SnO2
p6-12 (p234): 6.3.4 Other Semiconductor Nanoparticle Systems:Si,Agl,Ag2S,PbS
p6-13 (p235): 6.3.5 Nanoparticles of Layered Semiconductors:MoS2,Pbl2
p6-14 (p237): 6.3.6 Effects of Particle Surface,Size and Shape
p6-15 (p238): 6.4 Dynamic Properties of Metal Nanoparticles
p6-16 (p238): 6.4.1 Background and Theoretical Considerations
p6-17 (p240): 6.4.2 Gold(Au)Nanoparticles
p6-18 (p242): 6.4.3 Other Metal Nanoparticles:Ag,Cu,Sn,Ga and Pt
p6-19 (p242): 6.4.4 Effects of Surface,Size and Shape
p6-20 (p243): 6.5 Summary and Prospects
p6-21 (p244): References
p7 (p252): 7 Magnetic Characterization
p7-2 (p252): 7.1 Introduction
p7-3 (p255): 7.2 SQUID Magnetometry
p7-4 (p262): 7.3 M(?)ssbauer Spectroscopy
p7-5 (p273): 7.4 Neutron Powder Diffraction
p7-6 (p277): 7.5 Lorentz Microscopy
p7-7 (p281): 7.6 Summary
p7-8 (p281): References
p8 (p283): 8 Electrochemical Characterization
p8-2 (p283): 8.1 Introduction
p8-3 (p285): 8.2.1 Electrodeposition and Electrophoretic Deposition
p8-4 (p285): 8.2 Preparation of Nanostructured Electrode
p8-5 (p287): 8.2.2 Formation of Nanoparticles in Polymers
p8-6 (p288): 8.2.3 Electrochemical Self-Assembly
p8-7 (p289): 8.2.4 Mesoporous Electrodes
p8-8 (p291): 8.2.5 Composite Electrodes Consisting of Nanoparticles
p8-9 (p291): 8.2.6 Powder Microelectrode
p8-10 (p293): 8.3 Principles of Electrochemical Techniques
p8-11 (p293): 8.3.1 Impedance Spectroscopy
p8-12 (p300): 8.3.2 Potential Sweep Method
p8-13 (p304): 8.3.3 Potential Step Method
p8-14 (p307): 8.3.4 Controlled-Current Techniques
p8-15 (p312): 8.3.5 Electrochemical Quartz Crystal Microbalance
p8-16 (p316): 8.4 Application to Nanostructured Electrodes
p8-17 (p316): 8.4.1 Characterizing the Reversibility of Battery Electrode Materials
p8-18 (p319): 8.4.2 Characterizing the Transport Properties
p8-19 (p320): 8.5 Summary
p8-20 (p321): References
p9 (p326): 9 Mechanical Property Characterization
p9-2 (p326): 9.1 Elasticity Study of Metal Nanometer Films
p9-3 (p326): 9.1.1 Vibrating Reed Method
p9-4 (p328): 9.1.2 Elasticity Measurements on Ag and Al Films
p9-5 (p332): 9.1.3 Supermodulus Effect in Ag/Pd Multilayers
p9-6 (p336): 9.2 Mechanical Behavior of High-Density Nanocrystalline Gold
p9-7 (p348): 9.3.1 Introduction
p9-8 (p348): 9.3 FIB/TEM Observation of Defect Structure Underneath an Indentation
p9-9 (p349): 9.3.2 FIB Milling
p9-10 (p349): 9.3.3 Experimental Procedures
p9-11 (p349): 9.3.4 Load-Displacement Curve
p9-12 (p352): 9.3.5 TEM Observation
p9-13 (p355): 9.3.6 Conclusion
p9-14 (p355): References
p10 (p358): 10 Thermal Analysis
p10-2 (p358): 10.1 Introduction
p10-3 (p359): 10.2 Fundamental Techniques
p10-4 (p364): 10.3 Experimental Approach
p10-5 (p365): 10.3.1 Melting of Nanophases and Nanostructured Materials
p10-6 (p366): 10.3.2 Kinetics of Glass-Nanocrystal Transition and Grain Growth of Nanostructured Materials
p10-7 (p369): 10.3.3 Heat capacity of Nanostructured Materials
p10-8 (p370): 10.3.4 Interface Enthalpy of Nanostructured Materials
p10-9 (p372): 10.4 Data Interpretation
p10-10 (p372): 10.4.1 Size-Dependent Melting Thermodynamics of Nanophases
p10-11 (p374): 10.4.2 Glass-nanocrystal Transition Thermodynamics
p10-12 (p374): 10.5 Examples of Applications
p10-13 (p382): 10.6 Limitalions
p10-14 (p383): 10.7 Prospects
p10-15 (p384): References
p10-16 (p386): Index

These books, with of a total of 40 chapters, are a comprehensive and complete introductory text on the synthesis, characterization, and applications of nanomaterials. They are aimed at graduate students and researchers whose background is chemistry, physics, materials science, chemical engineering, electrical engineering, and biomedical science. The first part emphasizes the chemical and physical approaches used for synthesis of nanomaterials. The second part emphasizes the techniques used for characterizing the structure and properties of nanomaterials, aiming at describing the physical mechanism, data interpretation, and detailed applications of the techniques. The final part focuses on systems of different nanostructural materials with novel properties and applications.

v. 1. Synthesis
v. 2. Characterization
v. 3.,pt.1-2. Materials systems and applications I-II.

Nanoparticles play a vital role in high performance materials in high technology industries.

Title from ebook title screen (viewed July 9, 2004).

2024-06-13