close
1.

図書

図書
Charles E. Carraher, Jr
出版情報: Boca Raton, Fla. : CRC Press, c2017  xxvii, 560 p. ; 29 cm
所蔵情報: loading…
2.

図書

図書
Montgomery T. Shaw, William J. MacKnight
出版情報: Hoboken, N.J. : Wiley, c2018  xxii, 349 p. ; 26 cm
所蔵情報: loading…
目次情報: 続きを見る
Preface to the Fourth Edition
Preface to the Third Edition
Preface to the Second Edition
Preface to the First Edition
Introduction / 1:
Problems
General Reference Texts
References
Phenoraenological Treatment of Viscoelasticity / 2:
Elastic Modulus / A:
Transient Experiments / B:
Dynamic Experiments / C:
Low-Strain Measurements
Large Amplitude Oscillatory Shear (LAOS)
Microrheology / 3:
Boltzmann Superposition Principle / D:
Relationship Between The Creep Compliance And The Stress Relaxation Modulus / E:
Relationship Between Static And Dynamic Properties / F:
Connecting Creep Compliance and Stress Relaxation Modulus Using Laplace Transforms / Appendix 2-1:
Borel's Theorem / Appendix 2-2:
Geometries for the Measurement of Viscoelastic Functions / Appendix 2-3:
Linear Motion Geometries
Rotational Motion Geometries
Viscoelastic Models
Mechanical Elements
Maxwell Model
Voigt Model
Generalized Maxwell Model
Voigt-Kelvin model / 4:
Distributions Of Relaxation And Retardation Times
Molecular Theories-The Rouse Model
Application Of Flexible-Chain Models To Solutions
The Zimm Modification
Extension To Bulk Polymer
Reptation / G:
Manipulation Of The Rouse Matrix / Appendix 3-1:
Time-Temperature Correspondence
Four Regions Of Viscoelastic Behavior
Time-Temperature Superposition
Master Curves
The Wlf Equation
Molecular Interpretation Of Viscoelastic Response
Transitions and Relaxation in Amorphous Polymers / 5:
Phenomenology Of The Glass Transition
Theories Of The Glass Transition
Free-Volume Theory
Thermodynamic Theory
Kinetic Theories
Structural Parameters Affecting The Glass Transition
Relaxations In The Glassy State
Relaxation Processes In Networks
Physical Relaxation
Chemical Processes
Biopolymer Viscoelasticity
Biopolymer Sources
Humidity Control
Examples of Biopolymer Viscoelastic Response
Elasticity of Rubbery Networks / 6:
Thermodynamic Treatment
Statistical Treatment
Derivation
Energy Contribution
Phenomenological Treatment
Factors Affecting Rubber Elasticity
Effect of Degree of Crosslinking
Effect of Swelling
Effect of Fillers
Effect of Strain-Induced Crystallization
Statistics of a Polymer Chain / Appendix 6-1:
Equation of State for a Polymer Chain / Appendix 6-2:
Dielectric and NMR Methods / 7:
Dielectric Methods
Phenomenology
Molecular Interpretation of Dielectric Constant
Interfacial Polarization
Application to Polymers
Experimental Methods
Application of Dielectric Relaxation to Poly(methyl methacrylate)
Comparisons between Mechanical and Dielectric Relaxation for Polymers
Nuclear Magnetic Resonance Methods
Answers to Selected Problems
List of Major Symbols / Chapter 2:
List of Files on the Website
Author Index
Subject Index
Preface to the Fourth Edition
Preface to the Third Edition
Preface to the Second Edition
3.

図書

図書
H.N. Cheng, editor, Richard A. Gross, editor, Patrick B. Smith, editor ; sponsored by the ACS Division of Polymer Chemistry, Inc
出版情報: Washington, DC : American Chemical Society , [Oxford] : Distributed in print by Oxford University Press, c2018  xii, 435 p., 3 p. of col. plates ; 24 cm
シリーズ名: ACS symposium series ; 1310
所蔵情報: loading…
4.

図書

図書
Deborah D.L. Chung
出版情報: Singapore : World Scientific, c2019  xiii, 367 p. ; 24 cm
シリーズ名: Engineering materials for technological needs ; v. 3
所蔵情報: loading…
目次情報: 続きを見る
Preface
Introduction to carbon materials / 1:
Introduction / 1.1:
Graphite / 1.1.1:
Diamond / 1.1.2:
Fullerene / 1.1.3:
The graphite family / 1.2:
Graphite and turbostratic carbon / 1.2.1:
Carbon fibers and nanofibers / 1.2.2:
Carbon nanotubes / 1.2.3:
Intercalated graphite / 1.2.4:
Graphite oxide / 1.2.5:
Exfoliated graphite / 1.2.6:
Flexible graphite / 1.2.7:
Graphene / 1.2.8:
Activated carbon / 1.2.9:
Carbon black / 1.2.10:
Carbon-carbon composites / 1.2.11:
The diamond family / 1.3:
Diamond-like carbon / 1.3.1:
Graphane
The fullerene family / 1.4:
References
Structure of graphite and carbon in the graphite family / 2:
Fabrication of graphite / 2.2:
Polycrytalline graphite / 2.2.1:
Graphite flakes / 2.2.2:
Pyrolytic graphite / 2.2.3:
Properties of graphite / 2.3:
Reciprocal lattice / 2.4:
Electronic energy bands / 2.5:
Magnetic energy levels / 2.6:
Electrical properties / 2.7:
Lattice vibrations / 2.8:
Graphite intercalation compounds / 2.9:
Classification of graphite intercalation compounds / 2.9.1:
Covalent intercalation compounds / 2.9.2:
Graphite oxide (graphitic acid) / 2.9.2.1:
Carbon monofluoride (graphite monofluoride) / 2.9.2.2:
Tetracarbon monofluoride / 2.9.2.3:
Ionic intercalation compounds / 2.9.3:
Graphite-halogens / 2.9.3.1:
Graphite-alkali metals / 2.9.3.2:
Graphite-acid compounds / 2.9.3.3:
Graphite-halide compounds / 2.9.3.4:
Intercalated graphite fibers / 2.9.4:
Structure and formation / 2.10:
Viscoelastic and elastomeric properties / 2.10.2:
Dielectric properties / 2.10.3:
Thermal and electrical conductivities / 2.10.4:
Adsorption and filtration behavior / 2.10.5:
Electronic structure of graphene / 2.11:
Optical behavior / 3.3:
Defects in graphene / 3.4:
Mechanical behavior / 3.5:
Preparation of graphene / 3.6:
Preparation of graphene by the cleavage of graphite / 3.6.1:
Preparation of graphene by the mechanical disintegration of intercalated graphite / 3.6.2:
Preparation of graphene by the chemical reduction of graphene oxide / 3.6.3:
Preparation of graphene by nonoxidizing liquid exfoliation / 3.6.4:
Preparation of graphene by chemical vapor deposition / 3.6.5:
Graphene yarns / 3.7:
Graphene paper / 3.8:
Graphene foam / 3.9:
Graphene ink / 3.10:
Graphene quantum dots / 3.11:
Doping of graphene / 3.12:
Hybrids of graphene and carbon nanotubes / 3.13:
Hybrids of graphene and carbon fibers / 3.14:
Hybrids of graphene and electrochemical electrode materials / 3.15:
Fabrication / 4:
Structure / 4.3:
Squish ability and compaction / 4.4:
Application in thermal interface materials / 4.5:
Application as an electrically conductive additive / 4.6:
Dielectric behavior / 4.7:
Viscoelastic behavior / 4.8:
Nanoindentation behavior / 4.8.1:
Dynamic mechanical properties / 4.8.2:
Carbon black composites / 4.9:
Competing materials / 4.10:
Market and applications / 4.11:
Structure of activated carbon / 5:
Adsorption / 5.2:
Forms of activated carbon / 5.3:
Granular activated carbon / 5.3.1:
Powdered activated carbon / 5.3.2:
Extruded activated carbon / 5.3.3:
Bead activated carbon / 5.3.4:
Activated carbon assemblies / 5.4:
Honeycomb carbon filters / 5.4.1:
Activated carbon blocks with hollow channels / 5.4.2:
Activated carbon foam / 5.4.3:
Activated carbon foam assemblies / 5.4.4:
Activated carbon fiber fabric / 5.4.5:
Activated carbon composites / 5.4.6:
Fabrication of activated carbon / 5.5:
Steam activation / 5.5.1:
Gas activation / 5.5.2:
Chemical activation / 5.5.3:
Regeneration of activated carbon / 5.6:
Processing-structure-properly relationships of activated carbon / 5.7:
Applications of activated carbon / 5.8:
Water purification / 5.8.1:
Air purification / 5.8.2:
Gas purification / 5.8.3:
Waste treatment / 5.8.4:
Carbon dioxide capture / 5.8.5:
Heat pumps and refrigeration / 5.8.6:
Electrochemical components / 5.8.7:
Catalyst support / 5.8.8:
Market of activated carbon / 5.9:
Carbon fibers / 6:
Applications and market / 6.1:
Continuous fiber assemblies / 6.3:
Discontinuous fibers / 6.4:
Microstructure / 6.5:
Continuous carbon fibers vs. other materials / 6.6:
Carbon fiber composites / 6.8:
Carbon nanofibers and nanotubes / 7:
Structure of carbon nanofibers and nanotubes / 7.1:
Properties of carbon nanofibers and nanotubes / 7.3:
Mats and yams of CNFs/CNTs / 7.4:
Mats / 7.4.1:
Fabrication of mats / 7.4.1.1:
Electrical and electromagnetic behavior of mats / 7.4.1.2:
Mechanical behavior of mats / 7.4.1.3:
Electrochemical behavior of mats / 7.4.1.4:
Yarns / 7.4.2:
Fabrication of yarns / 7.4.2.1:
Mechanical behavior of yarns / 7.4.2.2:
Assemblies involving CNTs/CNFs / 7.5:
Vertically aligned CNTs / 7.5.1:
CMF/CNT with filled core channel / 7.5.2:
CNFs/CNTs grown on carbon fibers / 7.5.3:
CNTs grown on carbon black / 7.5.4:
CNTs grown on graphene, reduced graphene oxide or exfoliated graphite / 7.5.5:
Carbon deposited on CNTs / 7.5.6:
CNTs grown on alumina / 7.5.7:
CNTs grown on silica fibers / 7.5.8:
CNFs grown on cordierite / 7.5.9:
CNTs grown on metals / 7.5.10:
CNTs attached to polymers / 7.5.11:
CNFs/CNTs mixed with electrochemical electrode material / 7.5.12:
Fabrication of carbon nanofibers and nanotubes / 7.6:
Fabrication of carbon nanofibers/nanotubes from carbonaceous gases / 7.6.1:
Fabrication of carbon nanofibers from electro spun polymer nanofibers / 7.6.2:
Graphitization of carbon nanofibers / 7.6.4:
Index / 7.7:
Preface
Introduction to carbon materials / 1:
Introduction / 1.1:
5.

図書

図書
H.N. Cheng, Richard A. Gross, Patrick B. Smith, editor[s] ; sponsored by the ACS Division of Polymer Chemistry, Inc
出版情報: Washington, DC : American Chemical Society , [New York] : Distributed in print by Oxford University Press, c2015  xii, 496 p. ; 24 cm
シリーズ名: ACS symposium series ; 1192
所蔵情報: loading…
6.

図書

図書
Amit K. Naskar, Wesley P. Hoffman, editor[s] ; sponsored by the ACS Division of Polymer Chemistry
出版情報: Washington, DC : American Chemical Society , [New York] : Distributed in print by Oxford University Press, c2014  xii, 243 p., 4 p. of colored plates ; 24 cm
シリーズ名: ACS symposium series ; 1173
所蔵情報: loading…
7.

図書

図書
Jean-François Lutz, editor ... [et al.] ; sponsored by the ACS Division of Polymer Chemistry
出版情報: Washington, DC : American Chemical Society , [New York] : Oxford University Press, c2014  xii, 408 p., 9 p. of colored plates ; 24 cm
シリーズ名: ACS symposium series ; 1170
所蔵情報: loading…
8.

図書

図書
edited by Vikas Mittal
出版情報: Cambridge, UK : RSC Publishing, c2011  xiii, 317 p. ; 24 cm
シリーズ名: RSC nanoscience & nanotechnology ; no. 16
所蔵情報: loading…
目次情報: 続きを見る
Polymer Nanocomposites in Emulsion and Suspension: an Overview / Vikas MittalChapter 1:
Polymer Nanocomposites / 1.1:
Synthesis Methodologies for Polymer Nanocomposites / 1.2:
Template S ynthesis / 1.2.1:
In Situ Intercalative Polymerization / 1.2.2:
Melt Intercalation / 1.2.3:
Intercalation of Polymer or Prepolymer from Solution / 1.2.4:
Polymer Nanocomposites in Emulsion and Suspension / 1.3:
Acknowledgment
References
Polymer-Layered Double Hydroxide Nanocomposites by Emulsion and Suspension Polymerization / Longzhon Qiu ; Baojun QuChapter 2:
Introduction / 2.1:
Layered Double Hydroxides / 2.2:
Structure of LDHs / 2.2.1:
Properties of LDHs / 2.2.2:
Synthesis of LDHs / 2.2.3:
Organic Modification of LDHs / 2.2.4:
Polymer-LDH Nanocomposites / 2.3:
Structure of Polymer-LDH Nanocomposites / 2.3.1:
Conventional Strategies for Preparing Polymer-LDH Nanocomposites / 2.3.2:
Polymer-LDH Nanocomposites Prepared by Emulsion and Suspension Polymerization / 2.4:
Emulsion and Suspension Polymerization / 2.4.1:
Preparation of Polymer-LDH Nanocomposites via Emulsion and Suspension Polymerization / 2.4.2:
Properties and Potential Applications of Polymer-LDH Nanocomposites Obtained From Suspension and Emulsion Polymerization / 2.4.3:
Conclusion / 2.5:
Acknowledgments
Polymer-Clay Nanocomposite Particles by Direct and Inverse Emulsion Polymerization / Weihua (Marshall) Ming, Dirk-Jan Voorn ; Alex M. van HerkChapter 3:
Polymer-Clay Nanocomposite Particles by Direct Emulsion Polymerization / 3.1:
Polymer-Clay Nanocomposite Particles by Inverse Emulsion Polymerization / 3.3:
Clay Encapsulation by Emulsion Polymerization / 3.4:
General Approaches in Encapsulation of Inorganic Particles (in General) by Emulsion Polymerization / 3.4.1:
Encapsulation of Clay by (Mini)emulsion Polymerization / 3.4.2:
PMMA-based Montmorillonite Nanocomposites by Soap-free Emulsion Polymerization King-Fu Lin and Keng-Jen Lin / Chapter 4:
Fabrication of PMMA Nanocomposites Through Soap-free Emulsion Polymerization / 4.1:
Soap-free Emulsion Polymerization / 4.2.1:
Exfoliated MMT -PMMA Nanocomposites by Soap-free Emulsion Polymerization / 4.2.2:
Structure and Mechanical Properties of Exfoliated MMT-P(MA-co-MMA) Films / 4.3:
Grafting of P(MA-co-MMA) Chains on to Exfoliated MMT Nanoplatelets / 4.3.1:
Mechanical Properties of Exfoliated MMT-P(MA-co-MMA) Nanocomposite Film / 4.3.2:
Structure-Thermomechanical Property Relationship of Exfoliated MMT ûP (MA-co-MMA) Nanocomposite Films / 4.3.3:
Physical Properties of Exfoliated MMT ûPMMA Nanocomposite Films / 4.4:
Acrylic-Clay Nanocomposites by Suspension and Emulsion Polymerization / Urška Šebenik ; Matja Krajnc4.5:
Pressure-sensitive Adhesives Reinforced with Clays / 5.1:
Synthesis and Structure Characterization of Acrylic-Clay Nanocomposite Pressure-sensitive Adhesives / 5.3:
Properties of Acrylic-Clay Nanocomposite Pressure-sensitive Adhesives / 5.4:
Biodegradable Polymer-Clay Nanocomposite Fire Retardants via Emulsifier-free Emulsion Polymerization / Prafulla Kumar Sahoo5.5:
Experimental / 6.1:
Materials / 6.2.1:
Preparation of Nanocomposite / 6.2.2:
Characterization / 6.2.3:
Flame Retardancy / 6.2.4:
Biodegradation by Activated Sludge / 6.2.5:
Results and Discussion / 6.3:
FTIR Spectroscopy / 6.3.1:
XRD Analysis / 6.3.2:
TEM Analysis / 6.3.3:
Thermal Analysis / 6.3.4:
Mechanical Properties / 6.3.5:
Biodegradation / 6.3.6:
Abbreviations / 6.4:
Polymer Nanocomposites Prepared by Suspension Polymerization of Inverse Emulsion / Jintao. Yang ; Sin Zhu ; L. James LeeChapter 7:
Preparation of Polymer Nanocomposites via Inverse (Mini)emulsion Polymerization / 7.1:
Preparation of Polymer Nanocomposites via Suspension Polymerization / 7.3:
Polymer Synthesis via Suspension Polymerization of Inverse Emulsion / 7.4:
Preparation of Polymer Nanocomposites via Suspension Polymerization of Inverse Emulsion / 7.5:
Polymer Nanocomposites by Radiolytic Polymerization / Seong-Ho Choi ; Hai-Doo Kwen7.6:
Preparation of Polymer-Clay Nanocomposites by ?-Irradiation Polymerization / 8.1:
Preparation of Polymer-Metal Nanocomposites by ?-Irradiation Polymerization
Preparation of Polymer-CNT Nanocomposites by ?-Irradiation Polymerization
Polymer-Magnesium Hydroxide Nanocomposites by Emulsion Polymerization / Xiao-Lin Xie ; Sheng-Peng Liu ; Fei-Peng Du ; Yin- Wing MaiChapter 9:
Structure, Thermal Decomposition of MHs and Synthesis of MH Nanostructures / 9.1:
Crystal Structure of MHs / 9.2.1:
Thermal Decomposition of MHs / 9.2.2:
Synthesis of MH Nanostructures / 9.2.3:
Polymer-MH Nanocomposites by Emulsion Polymerization / 9.3:
In Situ Monomer-Nano-MH Emulsion Polymerization / 9.3.1:
In situ Combined Process of Precipitation and Emulsion Polymerization / 9.3.2:
Surface-initiated In'Situ Polymerization / 9.3.3:
Properties of Polymer-MH Nanocomposites by Emulsion Polymerization / 9.4:
Thermal Stability / 9.4.1:
Flammability / 9.4.2:
Rheological Properties / 9.4.3:
Conclusions and Future Trends / 9.5:
Polymer-Clay Nanocomposites by Miniemulsion Polymerization / Matej MicuÃœik ; Yuri Reyes ; Maria Paulis ; Jose Ramon LeizaChapter 10:
Organomodification of Clay / 10.1:
Morphology of Hybrid Monomer-Clay Miniemulsion Droplets/Particles / 10.3:
Pickering Miniemulsion / 10.3.1:
Encapsulation of Clay / 10.3.2:
Kinetics of Miniemulsion Polymerization in the Presence of Clay / 10.4:
Final Properties of Polymer-Clay Nanocomposites Prepared by Miniemulsion Polymerization / 10.5:
Towards Real Applications: High Solids Content and Reproducible Latexes / 10.7:
Conculsion
PAN-Silica-Clay. Nanocomposites by Emulsion Polymerization / Chunhua Cai ; Jiaping Lin ; Lan WeiChapter 11:
Synthesis and Structure of Polymer-Clay-Silica Nanocomposites / 11.1:
Thermal Properties of Polymer-Clay-Silica Nanocomposites / 11.3:
Mechanical Properties of Polymer-Clay-Silica Nanocomposites / 11.4:
Polymer-Clay Nanocomposites Prepared in Miniemulsion Using the RAFT Procesa / Ecldson Zengeni ; Austin Samakande ; Patrice C. Hartmann11.5:
Background to Controlled/Living Polymerization Using the RAFT Process / 12.1:
Controlled Polymerization Techniques and Their Applicability to PCNs / 12.4:
Preparation and Characterization of RAFT-mediated PCNs in Miniemulsion / 12.5:
Physical Properties of RAFT-mediated Polymer-Clay Nanocomposites / 12.6:
Thermomechanical Properties / 12.5.1:
Polymer-Clay Nanocomposite Particles and Soap-free Latexes Stabilized by Clay Platelets: State of the Art and Recent Advances / Elodie Bourgeat-Lami ; Nida Sheibat-Othman ; Amilton Martins Dos Santos12.5.2:
Clay Structure / 13.1:
Polymer-Clay Nanocomposites Produced by Conventional Emulsion Polymerization / 13.3:
Polymer-MMT Composite Latexes / 13.3.1:
Polymer-Laponite Nanocomposite Latexes / 13.3.2:
Soap-free Latexes Stabilized by Clay Platelets / 13.4:
Pickering Suspension and Miniemulsion Polymerizations: a Brief Overview / 13.4.1:
Soap-free Emulsion Polymerization Stabilized by Inorganic Solids / 13.4.2:
Laponite-armored Latexes Produced by Soap-free Emulsion Polymerization / 13.4.3:
Modeling and Online Monitoring by Calorimetry of the Preparation of Polymer-Laponite Nanocomposite Particles / 13.4.4:
Conclusions and Outlook / 13.5:
Subject Index
Polymer Nanocomposites in Emulsion and Suspension: an Overview / Vikas MittalChapter 1:
Polymer Nanocomposites / 1.1:
Synthesis Methodologies for Polymer Nanocomposites / 1.2:
9.

図書

図書
Charles E. Carraher, Jr.
出版情報: Boca Raton : CRC Press, c2010  xxiv, 510 p. ; 26 cm
所蔵情報: loading…
10.

図書

図書
edited by Andrew B. Lowe and Christopher N. Bowman
出版情報: Cambridge : Royal Society of Chemistry, c2013  xvii, 317 p ; 24 cm
シリーズ名: RSC polymer chemistry series ; 6
所蔵情報: loading…
文献の複写および貸借の依頼を行う
 文献複写・貸借依頼