Intelligent nanomaterials:
"Nanoscale materials exhibit extraordinary physical and chemical features which play a very important role in their applications in advanced tech- nologies. Due to their technological relevance, these materials have been a major driving force in academia as well as industries for laying down th...
Gespeichert in:
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| Format: | Buch |
| Sprache: | English |
| Veröffentlicht: |
Hoboken, New Jersey
Wiley
[2017]
|
| Ausgabe: | Second edition |
| Schriftenreihe: | Advanced materials series
|
| Schlagworte: | |
| Online-Zugang: | Inhaltsverzeichnis Klappentext |
| Zusammenfassung: | "Nanoscale materials exhibit extraordinary physical and chemical features which play a very important role in their applications in advanced tech- nologies. Due to their technological relevance, these materials have been a major driving force in academia as well as industries for laying down the foundation of new smart products for the benefit of society. During the last couple of decades, significant progress has been made towards developing new types of nanomaterials by various methods, i.e., physical, chemical and biological, including unconventional strategies directly inspired by nature. The functionality of these nanoscale structures increases when they are further functionalized with different atomic, molecular, and biological entities, etc., in the form of hybrids and composites. The intelligent mate- rials exhibit the capability of responding to the change generated by any signal...chemical, electrical, optical, etc....as a consequence of any external defined stimuli. Functional nanoscale materials are best suited for the class of intelligent materials. A lot of progress has already been made over the last decades towards intelligent materials, and the emergence of specific material features engineered by exploiting their excellent nanoscale fea- tures has been witnessed."... |
| Beschreibung: | Includes bibliographical references and index |
| Beschreibung: | xx, 562 Seiten Illustrationen, Diagramme |
| ISBN: | 9781119242482 |
Internformat
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| 245 | 1 | 0 | |a Intelligent nanomaterials |c edited by Ashutosh Tiwari, Yogendra Kumar Mishra, Hisatoshi Kobayashi and Anthony P.F. Turner |
| 250 | |a Second edition | ||
| 264 | 1 | |a Hoboken, New Jersey |b Wiley |c [2017] | |
| 300 | |a xx, 562 Seiten |b Illustrationen, Diagramme | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 490 | 0 | |a Advanced materials series | |
| 500 | |a Includes bibliographical references and index | ||
| 520 | |a "Nanoscale materials exhibit extraordinary physical and chemical features which play a very important role in their applications in advanced tech- nologies. Due to their technological relevance, these materials have been a major driving force in academia as well as industries for laying down the foundation of new smart products for the benefit of society. During the last couple of decades, significant progress has been made towards developing new types of nanomaterials by various methods, i.e., physical, chemical and biological, including unconventional strategies directly inspired by nature. The functionality of these nanoscale structures increases when they are further functionalized with different atomic, molecular, and biological entities, etc., in the form of hybrids and composites. The intelligent mate- rials exhibit the capability of responding to the change generated by any signal...chemical, electrical, optical, etc....as a consequence of any external defined stimuli. Functional nanoscale materials are best suited for the class of intelligent materials. A lot of progress has already been made over the last decades towards intelligent materials, and the emergence of specific material features engineered by exploiting their excellent nanoscale fea- tures has been witnessed."... | ||
| 650 | 4 | |a Nanostructured materials | |
| 650 | 4 | |a Smart materials | |
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| 700 | 1 | |a Tiwari, Ashutosh |d 1978- |0 (DE-588)1114183709 |4 edt | |
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| 999 | |a oai:aleph.bib-bvb.de:BVB01-029229145 | ||
Datensatz im Suchindex
| _version_ | 1804176671768576000 |
|---|---|
| adam_text | Contents
Preface xvii
Part 1 Nanomaterials, Fabrication and Biomedical
Applications
1 Electrospinning Materials for Skin Tissue Engineering 3
Beste Kinikoglu
1.1 Skin Tissue Engineering Scaffolds 4
1.1.1 Materials Used in Skin Tissue
Engineering Scaffolds 5
1.1.1.1 Natural Scaffolds 6
1.1.1.2 Synthetic Scaffolds 7
1.1.2 S caffold Production Techniques Used in
Skin Tissue Engineering 9
1.1.2.1 Freeze-drying 9
1.1.2.2 Electrospinning 11
1.2 Conclusions 14
References 15
2 Electrospinning: A Versatile Technique to Synthesize Drug
Delivery Systems 21
Xueping Zhang,Dong Liu and Tianyan You
2.1 Introduction 21
2.2 The Types of Delivered Drugs 22
2.2.1 Antitumor/Anticancer Drugs 22
2.2.2 Antibiotic 24
2.2.3 Growth Factors 26
2.2.4 Nucleic Acids 27
2.2.5 Proteins 28
v
vi Contents
2.3 Polymers Used in Electrospinning 29
2.3.1 Natural Polymers 30
2.3.1.1 Chitosan 30
2.3.1.2 Silk Fibroin 30
2.3.1.3 Cellulose Acetate 32
2.3.2 Synthetic Polymers 32
2.3.2.1 Synthetic Homopolymers 32
2.3.2.2 Synthetic Copolymers 33
2.3.3 Polymer Blends 34
2.3.3.1 Blends of Natural Polymers 34
2.3.3.2 Blends of Natural and Synthetic Polymers 35
2.3.3.3 Blends of Synthetic Polymers 36
2.3.3.4 Other Multicomponent Polymer Mixtures 36
2.4 The Development of Electrospinning Process for
Drug Delivery 36
2.4.1 Coaxial Electrospinning 37
2.4.2 Emulsion Electrospinning 38
2.4.3 Multilayer Electrospinning 39
2.4.4 Magnetic Nanofiber 40
2.4.5 Post-modification of Electrospun Scaffolds 41
2.5 Conclusions 41
Acknowledgment 42
References 42
Electrospray Jet Emission: An Alternative
Interpretation Invoking Dielectrophoretic Forces 51
Francesco Aliotta, Oleg Gerasymov and Pietro Calandra
3.1 Introduction 52
3.2 Electrospray: How It Works? 54
3.3 Historical Background 63
3.4 How the Current (and Wrong) Description of the
Electrospray Process Has Been Generated? 65
3.5 What Is Wrong in the Current Description? 68
3.6 Some Results Shedding More Light 70
3.7 Discriminating between Electrophoretic and
Dielectrophoretic Forces 72
3.8 Some Theoretical Aspects of Dielectrophoresis 76
3.9 Conclusions 83
References 86
Contents vii
4 Advanced Silver and Oxide Hybrids of Catalysts During
Formaldehyde Production 91
Anita Kováč Kralj
4.1 Introduction 92
4.2 The Catalysis 93
4.2.1 Limited Hybrid Catalyst Methodology 94
4.3 Case Study 95
4.3.1 Silver Process 95
4.3.2 Oxide Process 96
4.4 Limited Hybrid Catalyst Method for
Formaldehyde Production 97
4.4.1 Analyzing the Pure Catalyst Process 97
4.4.2 Graphical Presentation of Catalyst Process 97
4.4.3 Advanced Hybrid Catalyst Process 98
4.4.4 Choosing the Best Advanced Hybrid
Catalyst Process 101
4.4.5 Simulation of the Best Advanced Hybrid
Catalyst Process 102
4.5 Conclusion 104
4.6 Nomenclatures 105
References 105
5 Physico-chemical Characterization and Basic Research
Principles of Advanced Drug Delivery Nanosystems 107
Natassa Pippa, Stergios Pispas and Costas Demetzos
5.1 Introduction 108
5.2 Basic Research Principles and Techniques for the
Physicochemical Characterization of Advanced
Drug Delivery Nanosystems 108
5.2.1 Microscopy 108
5.2.1.1 Optical Microscopy 108
5.2.1.2 Electron Microscopy 109
5.2.1.3 Scanning Probe Microscopy 109
5.2.2 Thermal Analysis 111
5.2.2.1 Classification of Thermal Analysis
Techniques 111
5.2.2.2 Differential Scanning Calorimetry 113
viii Contents
5.2.3 Measurements of Size Distribution and
C-Potential of Nanocolloidal Dispersion
Systems and Their Evaluation
5.2.3.1 Photon Correlation Spectroscopy (PCS)
and Other Light-scattering Techniques
5.3 Conclusions
References
117
118
122
122
6 Nanoporous Alumina as an Intelligent Nanomaterial for
Biomedical Applications
Moom Sinn Aw and Dusan Losic
6.1 Introduction
6.2 Nanoporous Anodized Alumina as a
Drug Nano-carrier
6.2.1 Intelligent Properties of NAA
for Drug Delivery
6.3 Biocompatibility of NAA and NNAA Materials
6.4 NAA for Diabetic and Pancreatic Applications
6.5 NAA Applications in Orthopedics
6.6 NAA Applications for Heart, Coronary, and
Vasculature Treatment
6.7 NAA in Dentistry
6.8 Conclusions and Future Prospects
Acknowledgment
References
127
127
129
129
138
143
144
148
150
152
153
154
7 Nanomaterials: Structural Peculiarities, Biological Effects,
and Some Aspects of Application
N.F. Starodub, M.V. Taran, A.M. Katsev,
C. Bisio and M. Guidotti
7.1 Introduction
7.2 Physicochemical Properties Determining the
Bioavailability and Toxicity of Nanoparticles
7.3 Current Nanoecotoxicological Knowledge
7.3.1 Main Causes of NPs Toxicity
7.3.2 Risk Assessment for NPs in the Environment
7.3.3 Peculitiaries of Effects of Some NPs
on the Living Objects
7.3.3.1 Experiments with Luminescent Bacteria
7.3.3.2 Daphnias as Indicators of Influence of
Nanostructured Material
161
162
164
168
169
170
171
171
174
Contents ix
7.3.3.3 Investigations with Model Plants 174
7.3.3.4 Experiments with Plants under
Real Conditions 176
7.3.3.5 Effect of NPs of Some Oxide Metals
on the Bioluminescent Bacteria 177
7.3.3.6 Reaction of Daphnias on the
Effect of Some NPs 180
7.3.3.7 Effect of the Nanostructured Solids
on the Physiological Characteristics
of the Common Bean
(Phaseolus vulgaris) 181
7.3.3.8 Effect of the Colloidal NPs on the
Plants at Grow under Carbonate
Chlorosis Conditions 182
7.4 Modern Direction of the Application of
Nanostructured Solids in Detoxication Processes 186
7.4.1 From Conventional Decontamination
to Innovative Nanostructured Systems 186
7.5 Conclusions 188
Acknowledgments 189
References 189
Biomedical Applications of Intelligent Nanomaterials 199
M. D. Fahmy, H. E. Jazayeri, M. Razavi, M. Hashemi,
M. Omidi, M. Farahani, E. Salahinejad, A. Yadegari,
S, Pitcher and Lobat Tayebi
8.1 Introduction 200
8.2 Polymeric Nanoparticles 202
8.2.1 General Features 202
8.2.2 Poly-D,L-lactide-co-glycolide 203
8.2.3 Polylactic Acid 203
8.2.4 Polycaprolactone (PCL) 204
8.2.5 Chitosan 204
8.2.6 Gelatin 204
8.2.7 Potential and Challenges 205
8.3 Lipid-based Nanoparticles 206
8.3.1 Different Types 206
8.3.2 Applications 207
8.3.2.1 Intrinsic Stimuli 207
8.3.2.2 Extrinsic Stimuli 208
8.3.3 Potential and Challenges 211
x Contents
8.4 Carbon Nanostructures 213
8.4.1 General Feature 213
8.4.2 Zero-dimensional Carbon Nanostructures 213
8.4.3 One-dimensional Carbon Nanostructures 215
8.4.4 Two-dimensional Carbon Nanostructures 216
8.4.5 Three-dimensional Carbon Nanostructures 217
8.4.6 Potential and Challenges 218
8.5 Nanostructured Metals 219
8.5.1 Nitinol 219
8.5.2 Other Metallic Nanoparticles 220
8.5.3 Potential and Challenges 221
8.6 Hybrid Nanostructures 223
8.6.1 Smart Nanostructured Platforms for
Drug Delivery 224
8.6.1.1 Metal-based Smart Composite
and Hybrid Nanostructures 224
8.6.1.2 Carbon-based Smart Composite
and Hybrid Nanostructures 225
8.6.2 Smart Nanostructures for Diagnostic Imaging 226
8.6.2.1 Metal-based Smart Composite and
Hybrid Nanostructures 227
8.6.2.2 Carbon-based Smart Composite
and Hybrid Nanostructures 227
8.7 Concluding Remarks 228
References 229
Part 2 Nanomaterials for Energy, Electronics, and
Biosensing
9 Phase Change Materials as Smart Nanomaterials
for Thermal Energy Storage in Buildings 249
M. Kheradmand, Aí. Abdollahzadeh, M. Azenha
and J.L.B. de Aguiar
9.1 Introduction 250
9.2 Phase Change Materials: Definition, Principle of
Operation, and Classifications 252
9.3 PCM-enhanced Cement-based Materials 254
9.4 Hybrid PCM for Thermal Storage 255
Contents xi
9.5 Numerical Simulations 267
9.5.1 Numerical Simulation of Heat Transfers
in the Context of Building Physics 267
9.5.2 Governing Equations 268
9.6 Thermal Modeling of Phase Change 269
9.6.1 The Enthalpy-porosity Method 269
9.6.2 The Effective Heat Capacity Method 270
9.6.3 Numerical Simulation of
Small-scale Prototype 271
9.6.4 Results of the Numerical Simulations
of Prototype 272
9.6.5 Case Study of a Simulated Building 273
9.6.6 Results of Thermal Behavior and Energy Saving 276
9.6.7 Global Performance of a Building Systems with
Hybrid PCM 277
9.7 Nanoparticle-enhanced Phase Change Material 280
9.7.1 Modeling nanoparticle-enhanced PCM 282
9.7.2 Definition of the Case study 283
9.7.3 Results of Case Study with Nanoparticle-
enhanced Phase Change Material 284
9.8 Conclusions (General Remarks) 288
References 289
10 Nanofluids with Enhanced Heat Transfer Properties
for Thermal Energy Storage 295
Manila Chieruzzi, Adio Miliozzi, Luigi Torre and
José Maria Kenny
10.1 Introduction 296
10.2 Thermal Energy Storage 298
10.2.1 Sensible Heat Thermal Storage 301
10.2.2 Latent Heat Thermal Storage 303
10.2.3 Thermochemical Storage 309
10.2.4 FinalRemarks 313
10.3 Nanofluids for Thermal Energy Storage 313
10.3.1 Base Fluid 316
10.3.2 Nanoparticles 318
10.3.3 Methods of Nanofluid Preparation 327
10.4 Nanofluids Based on Molten Salts: Enhancement
of Thermal Properties 330
10.4.1 Specific Heat 331
10.4.2 Latent Heat of Fusion and
Melting Temperature 340
xii Contents
10.4.3 Thermal Conductivity 344
10.4.4 Thermal Storage 347
10.5 Conclusions 349
References 351
11 Resistive Switching of Vertically Aligned Carbon
Nanotubes for Advanced Nanoelectronic Devices 361
O.A. Ageev, Yu. F. Blinov, M.V. Il’ina, B.G. Konoplev
and V.A. Smirnov
11.1 Introduction 362
11.2 Theoretical Description of Resistive Switching
Mechanism of Structures Based on VACNT 363
11.2.1 The Modeling of the Deformation of the
VACNT Affected by a Local External
Electric Field 364
11.2.2 The Modeling of the Processes of Polarization
and Piezoelectric Charge Accumulation in a
Vertically Aligned Carbon Nanotube 370
11.2.3 The Modeling of the Memristor Effect
in the Structure Based on a Vertically
Aligned Carbon Nanotube 374
11.3 Techniques for Measuring the Electrical Resistivity
and Young s Modulus of VACNT Based on Scanning
Probe Microscopy 377
11.3.1 Techniques for Measuring Young’s Modulus
of VACNT Based on Nanoindentation 378
11.3.2 Techniques for Measuring the Electrical
Resistivity of VACNT Based on Scanning
Tunnel Microscopy 382
11.4 Experimental Studies of Resistive Switching in
Structures Based on VACNT Using Scanning
Tunnel Microscopy 384
References 391
12 Multi-objective Design of Nanoscale Double Gate MOSFET
Devices Using Surrogate Modeling and Global Optimization 395
Toufik Bentrcia, Fayçal Djeffaland Elasaad Chebaki
12.1 Introduction 396
12.2 Downscaling Parasitic Effects 400
Contents
xiii
12.2.1 Short Channel Effect 401
12.2.1.1 Drain-induced Barrier Lowering 401
12.2.1.2 Channel Length Modulation 401
12.2.1.3 Carrier Mobility Reduction 402
12.2.2 Quantum Mechanical Confinement Effect 402
12.2.2.1 Inversion Charge Displacement 403
12.2.2.2 Poly-silicon Gate Depletion 403
12.2.2.3 Threshold Voltage Shift 403
12.2.3 Hot-carrier Effect 404
12.2.3.1 Impact-ionization 404
12.2.3.2 Carrier Injection 405
12.2.3.3 Interface Trap Formation 405
12.3 Modeling Framework 405
12.3.1 Design of Computer Experiments 406
12.3.2 Metamodel Development 408
12.3.3 Multi ֊objective Optimization 410
12.4 Simulation and Results 412
12.5 Concluding Remarks 422
References 422
13 Graphene-based Electrochemical Biosensors:
New Trends and Applications 427
Georgia-Paraskevi Nikoleli, Stephanos
Spyridoula Bratakou, Dimitrios P. Nikolelis,
Nikolaos Tzamtzis and Vasillios Psychoyios
13.1 Introduction 428
13.2 Scope of This Review 429
13.3 Graphene and Sensors 430
13.4 Graphene Nanomaterials Used in Electrochemical
(Bio)sensors Fabrication 430
13.5 Graphe ne-based Enzymatic Electrodes 432
13.5.1 Graphene-based Electrochemical Enzymatic
Biosensors for Glucose Detection 432
13.5.2 Graphene-based Electrochemical Enzymatic
Biosensors for Hydrogen Peroxide Detection 434
13.5.3 Graphene-based Electrochemical Enzymatic
Biosensors for NADH Detection 435
13.5.4 Graphene-based Electrochemical Enzymatic
Biosensors for Cholesterol Detection 435
13.5.5 Graphene-based Electrochemical Enzymatic
Biosensors for Urea Detection 437
xiv Contents
13.6 Graphene-based Electrochemical DNA Sensors 437
13.7 Graphene-based Electrochemical Immunosensors 439
13.7.1 Graphene-based Electrochemical
Immunosensors for Biomarker Detection 440
13.7.2 Graphene-based Electrochemical
Immunosensors for Pathogen Detection 441
13.8 Commercial Activities in the Field of
Graphene Sensors 442
13.9 Recent Developments in the Field of
Graphene Sensors 442
13.10 Conclusions and Future Prospects 443
Acknowledgments 445
References 445
Part 3 Smart Nanocomposites, Fabrication, and
Applications
14 Carbon Fibers-based Silica Aerogel Nanocomposites 451
Agnieszka Šlosarczyk
14.1 Introduction to Nanotechnology 451
14.2 Chemistry of Sol-gel Process 454
14.2.1 Characterization and Application
of Silica Aerogels 454
14.2.2 Synthesis of Silica Gels via Sol-gel Process 456
14.2.3 Aging of Silica Gels 459
14.2.4 Methods of Drying of Silica Gels 460
14.3 Types of Silica Aerogel Nanocomposites 462
14.3.1 Reinforcing the Silica Aerogel and
Xerogel Structure in the Synthesis Stage 462
14.3.2 Metal-and Metal Oxide-based Silica Aerogels 464
14.3.3 Polymer-based Silica Aerogels 466
14.3.4 Fiber-based Silica Aerogels 468
14.4 Carbon Fiber-based Silica Aerogel Nanocomposites 476
14.4.1 Characterization of Carbon Fibers and
Chemical Modification of Their Surface 478
14.4.2 Synthesis of Silica Aerogel: Carbon Fiber
Nanocomposites in Relation to the
Type of Precursor 481
14.4.3 Drying of Silica Gel: Carbon Fiber
Nanocomposites 482
Contents xv
14.4.4 Research Methods Applied 484
14.4.5 Physical and Chemical Characterization of
Silica Aerogel and Xerogel Nanocomposites 485
14.5 Conclusions 493
References 494
15 Hydrogel-Carbon Nanotubes Composites for
Protection of Egg Yolk Antibodies 501
BellingeriRomina, Alustiza Fabrisio, Picco Natalia,
Motta Carlos, Grosso Maria C, Barbero Cesar,
Acevedo Diego and Vivas Adriana
15.1 Introduction 502
15.2 Polymeric Hydrogels 504
15.2.1 Synthetic and Natural Hydrogels 504
15.2.2 Intelligent Hydrogels 505
15.2.3 Characterization of Hydrogels 506
15.3 Carbon Nanotubes 507
15.3.1 Dispersion of Carbon Nanotubes 508
15.3.2 Toxicity of Carbon Nanotubes 509
15.3.3 Noncovalent Functionalization Strategies 509
15.3.4 Covalent Functionalization Strategies 510
15.4 Polymer-CNT Composites 511
15.4.1 Drug Delivery 512
15.4.2 Tissue Engineering 513
15.4.3 Electrical Cell Stimulation 514
15.4.4 Antimicrobial Materials 515
15.5 Egg Yolk Antibodies Protection 515
15.6 In Vitro Evaluation of Nanocomposite Performance 517
15.7 In Vivo Evaluation of Nanocomposite Performance 518
15.7.1 Nanotechnology for Bovine
Production Applications 519
15.7.2 Nanotechnology for Porcine
Production Applications 519
15.7.3 Nanotechnology Applications in Other
Animal Species 520
15.8 Concluding Remarks and Future Trends 521
References 522
xvi Contents
16 Green Fabrication of Metal Nanoparticles
Anamika Mubayi, Sanjukta Chatterji and Geeta Watal
16.1 Introduction
16.2 Development of Herbal Medicines
16.3 Green Synthesis of Nanoparticles
16.4 Characterization of Phytofabricated Nanoparticles
16.5 Impact of Plant-mediated Nanoparticles on
Therapeutic Efficacy of Medicinal Plants
16.5.1 Antidiabetic Potential
16.5.2 Antioxidant Potential
16.5.3 Antimicrobial Potential
16.6 Conclusions
References
Index
533
533
535
536
539
540
543
545
548
550
551
555
The 2nd edition of Intelligent Nanomaterials presents a detailed and comprehensive overview of the state-of-the-art
development of different nanoscale intelligent materials for advanced applications.
Apart from the fundamental aspects of fabrication and characterization of nanomaterials, this book
covers key advanced principles involved in the utilization of the functionalities presented by nanomaterials in
appropriate forms. It is very important to develop and understand the basic principles of how to utilize nanoscale
intelligent features in the desired fashion. These unique nanoscopic properties can either be accessed when the
nanomaterials are prepared in an appropriate form, for example, as composites, or in an integrated nanodevice
form for direct use as electronic sensing devices. In both cases, the nanostructure has to be appropriately
prepared, carefully handled, and properly integrated in order to efficiently access their intelligent features.
The book discusses these aspects in three themed sections: Nanomaterials, Fabrication and Biomedical
Applications; Nanomaterials for Energy, Electronics, and Biosensing; Smart Nanocomposites, Fabrication,
and Applications. The 16 chapters, all written by subject experts, cover the fundamental principles behind the
fabrication of different nanomaterials, composites and nanoelectronic devices as well as their applications in targeted
drug deliveries, energy harvesting, memory devices electrochemical biosensing and other advanced composite-based
biomedical applications.
This eagerly awaited 2nd edition has the following key topics: · Advanced silver and oxide hybrids of catalysts
during formaldehyde production · Physico-chemical characterisation and basic research principles of advanced drug
delivery nanosystems · Nanoporous alumina as an intelligent nanomaterial for biomedical applications · Nanomaterials:
Structural peculiarities, biological effects and some aspects of applications · Biomedical applications of intelligent
nanomaterials · Phase change materials as smart nanomaterials for thermal energy storage in buildings · Nanofluids
with enhanced heat transfer properties for thermal energy storage · Resistive switching of vertically aligned carbon
nanotubes for advanced nanoelectronics devices · Multi-objective design of nanoscale double gate MOSFET
devices using surrogate modelling and global optimization · Graphene-based electrochemical biosensors · Carbon
fibres-based silica aerogel nanocomposites · Hydrogel-carbon nanotubes composites for protection of egg yolk
antibodies
Audience
Scientists, researchers, students and engineers in materials science/ nanotechnology research, intelligent
systems and nanodevices, sensors, carbon nanomaterials, graphenes, nanobiomaterials, advanced biomaterials
applications. This book will also be useful for interdisciplinary PhD candidates for developing their fundamental
understanding about the subject and will be appropriate for upper and undergraduate level courses on
nanomaterials processing, properties and applications.
Ashutosh Tiwari is Secretary General, International Association of Advanced Materials; Chairman and Managing
Director of Tekidag AB (Innotech); Associate Professor and Group Leader, Smart Materials and Biodevices at the
world premier Biosensors and Bioelectronics Centre, IFM-Linköping University. He has more than 100 peer-reviewed
primary research publications in the field of materials science and nanotechnology and has edited/authored more
than 35 books on advanced materials and technology.
Yogendra Kumar Mishra is the Group Leader at Functional Nanomaterials, Institute for Materials Science in
University of Kiel, Germany. He obtained his PhD in 2008 from Jawaharlal Nehru University, New Delhi and his ‘Dr.
habil.’ title in 2015 from the University of Kiel. He has published more than 70 articles in referred journals.
Hisatoshi Kobayashi is a group leader of WPI Research center MANA, National Institute for Material Science,
Tsukuba Japan. He has published more than 180 publications, articles, books, and patents in the field of
biomaterial science and technology. His expertise is biomaterial science, biopolymers, biodegradable polymers,
nano-composites, nano-fibers, ophthalmologic and orthopedic devices.
Anthony (Tony) Turner’s name is synonymous with the field of biosensors and has over 750 publications and patents in
the field. In 2010, he joined Linköping University to create a new Centre for Biosensors and Bioelectronics. His previous
35- year academic career in the UK culminated in the positions of Principal of Cranfield University at Silsoe and
Distinguished Professor of Biotechnology. He was elected to the Royal Swedish Academy of Engineering Sciences in
2013 and was made a Fellow of the UK Royal Society of Chemistry in 1996.
|
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| ctrlnum | (OCoLC)966424871 (DE-599)BVBBV043818068 |
| dewey-full | 620.1/15 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 620 - Engineering and allied operations |
| dewey-raw | 620.1/15 |
| dewey-search | 620.1/15 |
| dewey-sort | 3620.1 215 |
| dewey-tens | 620 - Engineering and allied operations |
| discipline | Chemie / Pharmazie |
| edition | Second edition |
| format | Book |
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| id | DE-604.BV043818068 |
| illustrated | Illustrated |
| indexdate | 2024-07-10T07:35:54Z |
| institution | BVB |
| isbn | 9781119242482 |
| language | English |
| lccn | 016039435 |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-029229145 |
| oclc_num | 966424871 |
| open_access_boolean | |
| owner | DE-703 DE-19 DE-BY-UBM |
| owner_facet | DE-703 DE-19 DE-BY-UBM |
| physical | xx, 562 Seiten Illustrationen, Diagramme |
| publishDate | 2017 |
| publishDateSearch | 2017 |
| publishDateSort | 2017 |
| publisher | Wiley |
| record_format | marc |
| series2 | Advanced materials series |
| spelling | Intelligent nanomaterials edited by Ashutosh Tiwari, Yogendra Kumar Mishra, Hisatoshi Kobayashi and Anthony P.F. Turner Second edition Hoboken, New Jersey Wiley [2017] xx, 562 Seiten Illustrationen, Diagramme txt rdacontent n rdamedia nc rdacarrier Advanced materials series Includes bibliographical references and index "Nanoscale materials exhibit extraordinary physical and chemical features which play a very important role in their applications in advanced tech- nologies. Due to their technological relevance, these materials have been a major driving force in academia as well as industries for laying down the foundation of new smart products for the benefit of society. During the last couple of decades, significant progress has been made towards developing new types of nanomaterials by various methods, i.e., physical, chemical and biological, including unconventional strategies directly inspired by nature. The functionality of these nanoscale structures increases when they are further functionalized with different atomic, molecular, and biological entities, etc., in the form of hybrids and composites. The intelligent mate- rials exhibit the capability of responding to the change generated by any signal...chemical, electrical, optical, etc....as a consequence of any external defined stimuli. Functional nanoscale materials are best suited for the class of intelligent materials. A lot of progress has already been made over the last decades towards intelligent materials, and the emergence of specific material features engineered by exploiting their excellent nanoscale fea- tures has been witnessed."... Nanostructured materials Smart materials Nanostrukturiertes Material (DE-588)4342626-8 gnd rswk-swf Nanostrukturiertes Material (DE-588)4342626-8 s DE-604 Tiwari, Ashutosh 1978- (DE-588)1114183709 edt Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029229145&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis Digitalisierung UB Bayreuth - ADAM Catalogue Enrichment application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029229145&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA Klappentext |
| spellingShingle | Intelligent nanomaterials Nanostructured materials Smart materials Nanostrukturiertes Material (DE-588)4342626-8 gnd |
| subject_GND | (DE-588)4342626-8 |
| title | Intelligent nanomaterials |
| title_auth | Intelligent nanomaterials |
| title_exact_search | Intelligent nanomaterials |
| title_full | Intelligent nanomaterials edited by Ashutosh Tiwari, Yogendra Kumar Mishra, Hisatoshi Kobayashi and Anthony P.F. Turner |
| title_fullStr | Intelligent nanomaterials edited by Ashutosh Tiwari, Yogendra Kumar Mishra, Hisatoshi Kobayashi and Anthony P.F. Turner |
| title_full_unstemmed | Intelligent nanomaterials edited by Ashutosh Tiwari, Yogendra Kumar Mishra, Hisatoshi Kobayashi and Anthony P.F. Turner |
| title_short | Intelligent nanomaterials |
| title_sort | intelligent nanomaterials |
| topic | Nanostructured materials Smart materials Nanostrukturiertes Material (DE-588)4342626-8 gnd |
| topic_facet | Nanostructured materials Smart materials Nanostrukturiertes Material |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029229145&sequence=000003&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=029229145&sequence=000004&line_number=0002&func_code=DB_RECORDS&service_type=MEDIA |
| work_keys_str_mv | AT tiwariashutosh intelligentnanomaterials |