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1.

図書

図書
Donna J. Nelson, editor, Christopher N. Brammer, editor ; sponsored by the ACS Division of Fluorine Chemistry
出版情報: Washington, DC : American Chemical Society , [New York] : Distributed in print by Oxford University Press, c2011  viii, 174 p. ; 24 cm
シリーズ名: ACS symposium series ; 1064
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Introduction / Donna J. Nelson ; Dragan Nikic1:
The Nature of Molecular Association in Functionalized Low-Dimensional Carbon Structures
Fluorinated Carbon Nanomaterials: Xe / James S. Burgess ; Jeffrey W. Baldwin ; Jeremy T. Robinson ; Felipe A. Bulat ; Brian H. Houston2:
F2 Fluorination of Graphene
Association of Representative Amides and Aminoalcohols with SWCNT As Revealed by 1H NMR / Christopher N. Brammer ; Panneer Selvam Nagarajan ; Paramasivan T. Perumal3:
Fluorinated Porphyrins: From Organic Photovoltaics to Metal Nanocatalysts
Highly Fluorinated Porphyrins: From Ultra-Thin Films to Nanoparticles in Catalysis / Alessandro Varotto ; Gabriela Smeureanu ; Amit Aggarwal ; Charles Michael Drain4:
Energy Conversion Applications of Doped Complex Fluoride Lanthanides
Ligand Effects and Synthesis of Na / Jingning Shan ; Nan Yao ; Yiguang Ju5:
YF4 Based Up and Downconversion Colloidal Nanophosphors
Nanofluorides for Environmentally Benign Lighting and Energy Conversion in Solar Cells / Pushpal Ghosh ; Chantal Lorbeer ; Anja-Verena Mudring6:
Semiconductor Nanoparticles and Noble Metal Nanoparticles in Potential Fuel Cell Applications
Fluorinated Templates for Energy-Related Nanomaterials and Applications / Mohammed J. Meziani ; Fushen Lu ; Li Cao ; Christopher E. Bunker ; Elena A. Guliants ; Ya-Ping Sun7:
Synthesis, Functionalization, Characterization, and Application of Controlled Shape Nanoparticles in Energy Production / Simona E. Hunyadi Murph ; Steven M. Serkiz ; Elise B. Fox ; Hector Colon-Mercado ; Lindsay Sexton ; Matthew Siegfried8:
Indexes
Author Index
Subject Index
Introduction / Donna J. Nelson ; Dragan Nikic1:
The Nature of Molecular Association in Functionalized Low-Dimensional Carbon Structures
Fluorinated Carbon Nanomaterials: Xe / James S. Burgess ; Jeffrey W. Baldwin ; Jeremy T. Robinson ; Felipe A. Bulat ; Brian H. Houston2:
2.

図書

図書
Qing Wang,Lei Zhu, editor ; sponsored by the ACS Division of Polymeric Materials: Science and Engineering
出版情報: Washington, DC : American Chemical Society, c2010  xii, 226 p. ; 24 cm
シリーズ名: ACS symposium series ; 1034
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Preface
Nanostructure-Level Modeling of Nonlinear Energy Storage in Polymer-Ceramic Nanocomposites / Jeffrey P. Calame1:
Nanodielectrics for Energy Storage from First Principles Computations / N. Shi ; R. Ramprasad2:
Achieving Fast Discharge and Low Loss in Poly(vinylidene fluoride-co-chlorotrifluoroethylene)-graft-Polystyrene Films by Confined Ferroelectricity / Fanxiao Guan ; Zhongzhe Yuan ; Jing Wang ; Lei Zhu3:
Ferroelectric Polymer Based Nanocomposites for Electrical Energy Storage / Junjun Li ; Paisan Khanchaitit ; Qing Wang4:
Ultrafast IR Spectroscopic Study of Free Carrier Formation in OPV Polymer Blends / Ryan D. Pensack ; Kyle M. Banyas ; John B. Asbury5:
Recent Progress on Highly Efficient Bulk Heterojunction Polymer Solar Cells / Shengqiang Xiao ; Samuel C. Price ; Huaxing Zhou ; Wei You6:
Two Scale Roughness, Self-Cleaning, and Low Reflectivity Silicon Surface for Solar Cell Applications / Yonghao Xiu ; Yan Liu ; C. P. Wong7:
Dispersing and Functionalizing Carbon Nanotubes Using Cojugated Block Copolymers / Jianhua Zou ; Jianhua Liu ; Lei Zhai8:
Quantum Dots in Polymer Films for Light Selectivity / Weili Liu ; Ruigang Liu ; Yong Huang ; William Z. Xu ; Paul A. Charpentier9:
Proton Exchange Membrane Nanocomposites / Michael A. Hickner11:
Nanohybrid Nafion Membranes for Fuel Cells / Antonios Kelarakis ; Rafael Herrera Alonso ; Huiqin Lian ; Engin Burgaz ; Luiz Estevez ; Emmanuel P. Giannelis12:
Degradation Mitigation in PEM Fuel Cells Using Metal NanoParticle and Metal Oxide Additives / Panagiotis Trogadas ; Javier Parrondo ; Vijay Ramani13:
Indexes
Author Index
Subject Index
Preface
Nanostructure-Level Modeling of Nonlinear Energy Storage in Polymer-Ceramic Nanocomposites / Jeffrey P. Calame1:
Nanodielectrics for Energy Storage from First Principles Computations / N. Shi ; R. Ramprasad2:
3.

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
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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:
4.

図書

図書
Umesh P. Agarwal, editor, Rajai H. Atalla, editor, Akira Isogai, editor
出版情報: Washington, DC : American Chemical Society , [Oxford] : Distributed in print by Oxford University Press, c2017  x, 256 p., 6 p. of col. plates ; 24 cm
シリーズ名: ACS symposium series ; 1251
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Preface
The Nanostructures of Native Celluloses, Their Transformations upon Isolation, and Their Implications for Production of Nanocelluloses / Rajai H. Atalla and Rowan S. Atalla and Umesh P. Agarwal1:
Comparative Assessment of Methods for Producing Cellulose I Nanocrystals from Cellulosic Sources / Jia Mao and Hatem Abushammala and Nicole Brown and Marie-Pierre Laborie2:
Towards an Understanding of Cellulose Microfibril Dimensions from TEMPO-Oxidized Pulp Fiber / Zehan Li and Noppadon Sathitsuksanoh and Wei Zhang and Barry Goodell and Scott Renneckar3:
Raman Spectroscopy in the Analysis of Cellulose Nanomaterials / Umesh P. Agarwal4:
Internal Structure of Isolated Cellulose I Fibril Aggregates in the Water Swollen State / Per Tomas Larsson and Rose-Marie Pernilla Karlsson and Per-Olof Westlund and Lars Wågberg5:
Rheological Properties of Jute-Based Cellulose Nanofibers under Different Ionic Conditions / Lihong Geng and Ali Naderi and Yimin Mao and Chengbo Zhan and Priyanka Sharma and Xiangfang Peng and Benjamin S. Hsiao6:
Rice Straw Nanocelluloses: Process-Linked Structures, Properties, and Self-Assembling into Ultra-Fine Fibers / Feng Jiang and You-Lo Hsieh7:
Branched Structures of Softwood Celluloses: Proof Based on Size-Exclusion Chromatography and Multi-Angle Laser-Light Scattering / Yuko Ono and Tsuguynki Saito and Akira Isogai8:
Tissue Engineering Using Plant-Derived Cellulose Nanofibrils (CNF) as Scaffold Material / Kristin Syverud9:
TEMPO/Laccase/O2 Oxidation of Native Cellulose for the Preparation of Cellulose Nanofibers / Jie Jiang and Yimin Fan10:
Nanocellulose: Common Strategies for Processing of Nanocomposites / Marcos Mariano and Alain Dufresne11:
Experiences with Scaling-Up Production of TEMPO-Grade Cellulose Nanofibrils / Richard S. Reiner and Alan W. Rudie12:
Editors' Biographies
Indexes
Author Index
Subject Index
Preface
The Nanostructures of Native Celluloses, Their Transformations upon Isolation, and Their Implications for Production of Nanocelluloses / Rajai H. Atalla and Rowan S. Atalla and Umesh P. Agarwal1:
Comparative Assessment of Methods for Producing Cellulose I Nanocrystals from Cellulosic Sources / Jia Mao and Hatem Abushammala and Nicole Brown and Marie-Pierre Laborie2:
5.

電子ブック

EB
Joseph H. Koo, University of Texas
出版情報:   1 online resource (xix, 697 pages)
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6.

図書

図書
edited by Tito Trindade, Ana L. Daniel da Silva
出版情報: Singapore : Pan Stanford Publishing, c2011  xxii, 289, 4 p. ; 24 cm
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List of Figures
List of Tables
Preface
From Nanoparticles to Nanocomposites: A Brief Overview / 1:
Nanoscience and Nanotechnology: An introduction / 1.1:
Nanoparticles' Diversity / 1.2:
Quantum dots / 1.2.1:
Iron oxides / 1.2.2:
Metal nanoparticles / 1.2.3:
Surface Modification of Nanoparticles / 1.3:
Ligand exchange reactions / 1.3.1:
Inorganic nanocoating / 1.3.2:
Encapsulation in polymers / 1.3.3:
Designing Biointerfaces over Nanoparticles / 1.4:
Challenges for the Future... Nanosafety for Today / 1.5:
Polymers for Biomedical Applications: Chemical Modification and Biofunctionalization / 2:
Drug Delivery Systems / 2.1:
Hydrogels / 2.2:
Application of hydrogels / 2.2.1:
Types of hydrogels / 2.2.2:
Bioadhesives / 2.3:
Surface Modification / 2.4:
Surface modification by ultra-violet radiation / 2.4.1:
Plasma treatment / 2.4.2:
Plasma generation / 2.4.2.1:
Plasma polymerization and surface modification of polymers / 2.4.2.2:
Concluding Remarks / 2.5:
Nanocapsules as Carriers for the Transport and Targeted Delivery of Bioactive Molecules / 3:
Introduction / 3.1:
Polymeric Nanocapsules: Production and Characterization / 3.2:
Nanocapsules made of synthetic polymers / 3.2.1:
Polyacrylate nanocapsules / 3.2.1.1:
Polyester nanocapsules / 3.2.1.2:
Nanocapsules made of natural polymers / 3.2.2:
Lipid nanocapsules / 3.2.3:
Therapeutical Applications of Nanocapsules / 3.3:
Nanocapsules for oral drug delivery / 3.3.1:
Nanocapsules for oral peptide delivery / 3.3.1.1:
Nanocapsules for oral delivery of lipophilic low molecular weight drugs / 3.3.1.2:
Nanocapsules as nasal drug carriers / 3.3.2:
Nanocapsules as ocular drug carriers / 3.3.3:
Nanocapsules in cancer therapy / 3.3.4:
Nanocapsules as carriers for gene therapy / 3.3.5:
Conclusions / 3.4:
Inorganic Nanoparticles Biofunctionalization / 4:
Bioeonjugation of Nanoparticles / 4.1:
Nanoparticles and Their Surface Properties / 4.2:
Surface capping of nanoparticles / 4.2.1:
Semiconductor quantum dots and metallic nanoparticles / 4.2.2:
Silica nanoparticles and silica encapsulation / 4.2.3:
Attachment Schemes / 4.3:
Covalent attachment / 4.3.1:
Non-covalent attachment / 4.3.2:
Affinity binding / 4.3.3:
Specific Cases / 4.4:
Proteins / 4.4.1:
DNA / 4.4.2:
Avidin / 4.4.3:
Phospholipid encapsulation and functionalization / 4.4.4:
Applications / 4.5:
Cellular imaging / 4.5.1:
Drug delivery / 4.5.2:
Bioluminescence resonance energy transfer / 4.5.3:
Hyperthermia / 4.5.4:
Conclusion / 4.6:
Silica-Based Materials: Bioprocesses and Nanocomposites / 5:
Natural Silica Nanocomposites / 5.1:
Diatom biosilica / 5.1.1:
Sponge biosilica / 5.1.3:
(Bio)-technological applications of biosilica / 5.1.4:
Biomimetic Silica Nanocomposites / 5.2:
Silica nanocomposites based on natural templates / 5.2.1:
Silica nanocomposites based on model templates / 5.2.3:
Synthetic peptides / 5.2.3.1:
Synthetic polyamines / 5.2.3.2:
Biological templates / 5.2.3.3:
Biomimetism: How far can we go? / 5.2.4:
Bio-Inspired Silica Nanocomposites / 5.3:
Biotechnological and medical applications / 5.3.1:
Perspectives / 5.3.3:
Synthetic Strategies for Polymer-Based Nanocomposite Particles / 6:
Surfaces and Interfaces: Chemical Modification of Nanoparticles / 6.1:
In situ Synthetic Strategies for Polymer-Based Colloidal Nanocomposites / 6.3:
In situ preparation of the fillers / 6.3.1:
Sol-gel methods / 6.3.1.1:
In situ polymerization of the matrix / 6.3.2:
Organic solvent-based methods: Dispersion polymerization / 6.3.2.1:
Water-based methods: Emulsion and miniemulsion polymerization / 6.3.2.2:
Controlled polymerization: Surface initiated polymerization(SIP) / 6.3.3:
Atom Transfer Radical Polymerization Atrp / 6.3.3.1:
Reversible Addition Fragmentation chain transfer (Raft) polymerization / 6.3.3.2:
Combined controlled polymerization mechanisms / 6.3.3.3:
Functionalization of Polymer-Based Nanocomposites for Bio-Applications / 6.4:
Final Remarks / 6.5:
Synthesis of Nanocomposite Particles Using Supercritical Fluids: A Bridge with Bio-applications / 7:
Supercritical Fluids: Definition and Current use in, Bio-Applications / 7.1:
Definition / 7.2.1:
Scps in biomedical applications / 7.2.2:
Development of drug delivery systems / 7.2.2.1:
scC02 for purification and sterilization / 7.2.2.2:
Can Scfs be Used to Introduce Inorganic NPs into Polymers? / 7.3:
Formation of hybrid organic-inorganic NPs in Scps(route 1) / 7.3.1:
Encapsulation of inorganic NPs into a polymer shell (route 2) / 7.3.2:
Polymer swelling and in situ growth of inorganic NPs (route 3) / 7.3.3:
Polymer swelling by scC02 / 7.3.3.1:
Chemical transformation of impregnated metal precursor / 7.3.3.2:
Biocomposites Containing Magnetic Nanoparticles / 7.4:
Magnetic Properties / 8.1:
Magnetism at nanoscale level: Concepts and main phenomena / 8.2.1:
Basic concepts / 8.2.1.1:
Systems with interactions between magnetic centers / 8.2.1.2:
Superparamagnetism / 8.2.1.3:
Magnetism concepts subjacent to bio-applicatons / 8.2.2:
Magnetic separation and drug delivery / 8.2.2.1:
Magnetic resonance imaging (Mri) / 8.2.2.2:
Magnetic hyperthermia / 8.2.2.3:
Magnetic Nanoparticles for Bio-Applications / 8.3:
Iron oxide nanoparticles / 8.3.1:
Metallic nanoparticles / 8.3.2:
Metal alloy nanoparticles / 8.3.3:
Bimagnetic nanoparticles / 8.3.4:
Strategies of Synthesis of Magnetic Biocomposite Nanoparticles / 8.4:
In situ formation of magnetic nanoparticles / 8.4.1:
Other magnetic nanoparticles / 8.4.1.1:
Encapsulation of magnetic nanoparticles within biopolymers / 8.4.2:
Conclusions and Future Outlook / 8.5:
Multifunctional Nanoeomposite Particles for Biomedical Applications / 9:
Types of Multifunctional Magnetic-Fluorescent Nanocomposites / 9.1:
Main Approaches to the Preparation of Multifunctional Magnetic-Fluorescent Nanocomposites / 9.3:
Silica coated magnetic-fluorescent nanoparticles / 9.3.1:
Organic polymer coated magnetic cores treated with fluorescent entities / 9.3.2:
Ionic assemblies of magnetic cores and fluorescent entities / 9.3.3:
Fluoreseently-labeled lipid coated magnetic nanoparticles / 9.3.4:
Magnetic core directly linked to fluorescent entity via a molecular spacer / 9.3.5:
Magnetic cores coated by fluorescent semiconducting shells / 9.3.6:
Magnetically-doped Qds / 9.3.7:
Magnetic nanoparticles and Qds embedded within a polymer or silica matrix / 9.3.8:
Biomedical Applications / 9.4:
Bio-imaging probes / 9.4.1:
Cell tracking, sorting and bioseparation / 9.4.2:
Applications in nanomedicine / 9.4.3:
Bio-Applications of Functionalized Magnetic Nanoparticles and Their Nanocomposites / 9.5:
Fundaments of Nanomagnetism / 10.1:
Single-domain particles / 10.2.1:
Magnetic anisotropy energy / 10.2.2:
Fundaments of Colloidal Stability / 10.2.3:
Bio-Applications of Magnetic Nanoparticles / 10.4:
Magnetic separation / 10.4.1:
Nuclear magnetic resonance imaging (Mri) / 10.4.2:
Contrast agents based on superparamagnetic nanomagnets / 10.4.3.1:
Magnetobiosensors / 10.4.4:
Magnetobiosensors based on magnetorelaxometry / 10.4.4.1:
Magnetobiosensors based on magnetoresistance / 10.4.4.2:
Magnetosensors based on Hall effect / 10.4.4.3:
Magnetoplasmonics / 10.4.4.4:
Summary and Outlook / 10.4.5:
Anti-Microbial Polymer Nanocomposites / 11:
Packaging / 11.1:
Textiles / 11.1.2:
Coatings / 11.1.3:
Antimicrobial coatings / 11.1.3.1:
Medicine, pathology and surgical implants/ biomedical coatings / 11.1.3.2:
Anti-Microbial Polymer-Based Nanocomposites / 11.2:
Mechanisms of Antibacterial Action / 11.3:
Detection of microbes / 11.3.1:
Control of microbial growth / 11.3.2:
Environmental and Health Concerns / 11.4:
Biosensing Applications Using Nanoparticles / 12:
Biosensors: A Definition / 12.1:
Uses of Gold Nanoparticles / 12.2:
Tailoring biointerfaces over gold nanoparticles / 12.2.1:
Biosensing applications of gold nanoparticles / 12.2.2:
Crosslinking-based biosensing / 12.2.2.1:
Non-crosslmking-based biosensing / 12.2.2.2:
Semiconductor Quantum Dots / 12.3:
Properties of quantum dots / 12.3.1:
Biosensing with quantum dots / 12.3.2:
Immunosensing / 12.3.2.1:
Dna assays / 12.3.2.2:
Resonance energy transfer-based assays / 12.3.2.3:
Outlook Remarks / 12.4:
Index
List of Figures
List of Tables
Preface
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