Self-assembly and nanotechnology: a force balance approach
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Sprache: | English |
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Hoboken, NJ
Wiley
2008
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Online-Zugang: | Publisher description Contributor biographical information Inhaltsverzeichnis |
Beschreibung: | XVI, 344 S. Ill., graph. Darst. |
ISBN: | 9780470248836 |
Internformat
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300 | |a XVI, 344 S. |b Ill., graph. Darst. | ||
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650 | 4 | |a Nanostructured materials |x Design | |
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adam_text | SELF-ASSEMBLY AND
NANOTECHNOLOGY
A Force Balance
Approach
Yoon S Lee
Scientific Information Analyst
Chemical Abstracts Service
A Division of the American Chemical Society
Columbus, Ohio
WILEY
A JOHN WILEY amp; SONS, INC , PUBLICATION
CONTENTS
Preface and Acknowledgments xv
PART I SELF-ASSEMBLY 1
1 UNIFIED APPROACH TO SELF-ASSEMBLY 3
1 1 Self-Assembly through Force Balance 5
1 2 General Scheme for the Formation of Self-Assembled
Aggregates 8
1 3 General Scheme for Self-Assembly Process 10
1 4 Concluding Remarks 17
References 18
2 INTERMOLECULAR AND COLLOIDAL FORCES 21
2 1 Van der Waals Force 22
2 2 Electrostatic Force: Electric Double-Layer 28
2 3 Steric and Depletion Forces 33
2 4 Solvation and Hydration Forces 37
241 Solvation Force 37
242 Hydration Force 38
2 5 Hydrophobic Effect 39
2 6 Hydrogen Bond 42
References 44
3 MOLECULAR SELF-ASSEMBLY IN SOLUTION I: MICELLES 47
3 1 Surfactants and Micelles 48
3 2 Physical Properties of Micelles 50
321 Micellization 50
322 Critical Micellar Concentration and Aggregation
Number 51
323 Counterion Binding 53
vii
CONTENTS
viii
3 3 Thermodynamics of Micellization 53
331 Mass-Action Model 54
332 Pseudo-phase Separation Model 55
333 Hydrophobie Effect and Enthalpy-Entropy
Compensation 57
3 4 Micellization versus General Scheme of Self-Assembly 58
341 Change of Micelle Structures 58
342 General Scheme of Micellization 60
343 Concept of Force Balance and Surfactant Packing
Parameter 60
3 5 Multicomponent Micelles 63
3 6 Micellar Solubilization 66
3 7 Applications of Surfactants and Micelles 68
371 Micellar Catalysis 69
References 71
4 MOLECULAR SELF-ASSEMBLY IN SOLUTION II: BILAYERS,
LIQUID CRYSTALS, AND EMULSIONS 75
4 1 Bilayers 76
411 Bilayer-Forming Surfactants 76
412 Bilayerization 77
413 Physical Properties of Bilavers 79
4 2 Vesicles Liposomes, and Niosomes 80
421 Physical Properties of Vesicles 80
422 Micellar Catalysis on Vesicles 82
4 3 Liquid Crystals 83
431 Thermotropic Liquid Crystals 84
432 Lyotropic Liquid Crystals 87
4321 Concentration-Temperature Phase Diagram 87
4322 Ternary Surfactant-Water-Oil (or
Co-surfactant) Phase Diagram 90
4 4 Emulsions 92
441 Microemulsions 93
442 Reverse Micelles 95
443 Macroemulsions 97
444 Micellar Catalysis on Microemulsions 99
References 100
5 COLLOIDAL SELF-ASSEMBLY 103
5 1 Forces Induced by Colloidal Phenomena 104
511 Surface Tension and Capillarity 105
512 Contact Angle and Wetting 108
CONTENTS ix
513 Adhesion 109
514 Gravity and Diffusion 110
515 Pressures by Osmotic and Donnan Effects 112
516 Electrokinetic Force 114
517 Magnetophoretic Force 116
518 Force by Flow 117
5 2 Force Balance for Colloidal Self-Assembly 118
5 3 General Scheme for Colloidal Self-Assembly 120
5 4 Micelle-like Colloidal Self-Assembly: Packing Geometry 121
5 5 Summary 122
References 123
6 SELF-ASSEMBLY AT INTERFACES 125
6 1 General Scheme for Interfacial Self-Assembly 126
611 Surfaces and Interfaces 126
612 Force Balance with Interfaces 127
6 2 Control of Intermolecular Forces at Interfaces 129
621 Packing Geometry: Balance with Attractive and
Repulsive Forces 129
622 Packing with Functional Groups: Balance with
Directional Force 130
6221 Building Units with Multifunctional Sites 130
6222 Building Units with Single Functional Sites 132
623 Packing of Nonamphiphilic Building Units 134
6 3 Self-Assembly at the Gas-Liquid Interface 135
631 Langmuir Monolayer 135
632 Surface Micelles 138
6 4 Self-Assembly at the Liquid-Solid Interface 139
6 5 Self-Assembly at the Liquid-Liquid Interface 140
6 6 Self-Assembly at the Gas-Solid Interface 140
6 7 Interface-Induced Chiral Self-Assembly 142
References 145
7 BIO-MIMETIC SELF-ASSEMBLY 149
7 1 General Picture of Bio-mimetic Self-Assembly 150
7 2 Force Balance Scheme for Bio-mimetic Self-Assembly 153
7 3 Origin of Morphological Chirality and Diversity 155
731 Chirality of Building Units 155
732 Asymmetric Structure of Building Units 157
733 Multiple Hydrogen Bonds 158
734 Cooperative Balance of Geometry and Bonding 159
735 Induced Asymmetric Packing 160
X
CONTENTS
7 4 Symmetric Bio-mimetic Self-Assembled Aggregates 161
741 H-and J-Aggregates 161
742 Molecular Capsules 163
7 5 Gels: Networked Bio-mimetic Self-Assembled Aggregates 163
7 6 Properties of Bio-mimetic Self-Assembled Aggregates 165
761 Directionality Site-Specificity, and Chirality 165
762 Hierarchicality 166
763 Complementarity 167
764 Chiroptical Properties 167
7 7 Future Issues 168
References 168
PART II NANOTECHNOLOGY 171
8 IMPLICATIONS OF SELF-ASSEMBLY FOR NANOTECHNOLOGY 173
8 1 General Concepts and Approach to Nanotechnology 173
8 2 Self-Assembly and Nanotechnology Share the Same Building
Units 176
8 3 Self-Assembly and Nanotechnology Are Governed by
the Same Forces 177
8 4 Self-Assembly versus Manipulation for the Construction of
Nanostructures 177
8 5 Self-Aggregates and Nanotechnology Share the Same
General Assembly Principles 178
8 6 Concluding Remarks 180
References 181
9 NANOSTRUCTURED MATERIALS 183
9 1 What Are Nanostructured Materials? 184
9 2 Intermolecular Forces During the Formation of
Nanostructured Materials 185
9 3 Sol-Gel Chemistry 187
9 4 General Self-Assembly Schemes for the Formation of
Nanostructured Materials 189
9 5 Micro-, Meso-, and Macroporous Materials 190
9 6 Mesostructured and Mesoporous Materials 192
961 Formation of Mesoporous Silica with Hexagonal
Structure 193
962 Structural Control of Mesostructured and Mesoporous
Materials 195
CONTENTS XI
963 Epitaxial Analysis at the Micelle-Silica Interface 198
964 Charge Matching at the Micelle-Silica Interface 203
965 Characterization of Mesostructured and Mesoporous
Materials 204
9 7 Organic-Inorganic Hybrid Mesostructured and Mesoporous
Materials 205
9 8 Microporous and Macroporous Materials 206
981 Co-Self-Assembly for the Formation of Microporous
Materials 207
982 Emulsions for the Formation of Macroporous
Materials 209
983 Colloidal Self-Assembly for the Formation of
Macroporous Materials 210
9 9 Applications of Nanostructured and Nanoporous Materials 211
9 10 Summary and Future Issues 214
References 216
10 NANOPARTICLES: METALS, SEMICONDUCTORS, AND OXIDES 221
10 1 What are Nanoparticles? 222
10 2 Intermolecular Forces During the Synthesis of Nanoparticles 224
10 3 Synthesis of Nanoparticles 226
10 3 1 Direct Synthesis: Confinement-by-Adsorption 227
10 3 2 Synthesis within Preformed Nanospace 229
10 321 Surfactant Self-Assembled Aggregates 230
10 322 Bio-mimetic Self-Assembled Aggregates 232
10 323 Dendritic Polymers 233
10 324 Nanoporous Solids 233
10 325 Directed Growth by Soft Epitaxy 234
10 326 Directed Growth by Hard Epitaxy 234
10 3 3 Nanoparticle Synthesis with Nonconventional Media 236
10 331 Supercritical Fluids 236
10 332 Ionic Liquids 237
10 4 Properties of Nanoparticles 238
10 4 1 Quantum Size Effect 238
10 411 Optical Properties of Semiconductors 238
10 412 Optical Properties of Noble Metals 240
10 413 Electromagnetic Properties of Noble Metals 240
10 414 Electric Properties of Metals 241
10 4 2 Surface Atom Effect 241
10 5 Applications of Nanoparticles 243
10 5 1 Chemical and Biological Sensors 243
10 5 2 Optical Sensors 244
10 5 3 Nanocomposites and Hybrid Materials 245
XII
CONTENTS
10 5 4 Catalysis 245
10 5 5 Functional Fluids 245
10 6 Summary and Future Issues 246
References 247
11 NANOSTRUCTURED FILMS 249
11 1 What Is Nanostructured Film? 249
11 2 General Scheme for Nanostructured Films 251
11 3 Preparation and Structural Control of Nanostructured Films 252
11 3 1 Self-Assembled Monolayer (SAM) 252
11 3 2 Layer-by-Layer Assembly 255
11 3 3 Vapor-Deposited Films 256
11 3 4 Sol-Gel Processed Films 258
11 3 5 Langmuir-Blodgett (LB) Films 259
11 4 Properties and Applications of Nanostructured Films 263
11 4 1 Nanoporous Films 263
11 4 2 Nanolayered Films 263
11 4 3 Nanopatterned Films 264
11 4 4 Monolayer: Model Membrane 265
11 5 Summary and Future Issues 266
References 267
12 NANOASSEMBLY BY EXTERNAL FORCES 271
12 1 Force Balance and the General Scheme of Self-Assembly
Under External Forces 272
12 2 Colloidal Self-Assembly Under External Forces 273
12 2 1 Capillary Force 273
12 2 2 Electric Force 275
12 2 3 Magnetic Force 277
12 2 4 Flow 278
12 2 5 Mechanical Force 279
12 2 6 Force by Spatial Confinement 280
12 2 7 Other Forces 282
12 271 Laser-Optical Force 282
12 272 Ultrasound 282
12 273 Gravity and Centrifugal Forces 282
12 3 Molecular Self-Assembly Under External Forces 283
12 3 1 Flow 283
12 3 2 Magnetic Field 285
12 3 3 Concentration Gradient 285
12 3 4 Confinement 286
12 3 5 Gravity and Centrifugal Forces 287
CONTENTS Xiii
12 4 Applications of Colloidal Aggregates 287
12 4 1 Optical Band Gap 287
12 4 2 Nanostructured Materials 288
12 5 Summary and Future Issues 288
References 290
13 NANOFABRICATION 293
13 1 Self-Assembly and Nanofabrication 294
13 2 Unit Fabrications 296
13 2 1 Jointing 296
13 2 2 Crossing and Curving 297
13 2 3 Alignment and Stacking 298
13 2 4 Reconstruction, Deposition, and Coating 299
13 2 5 Symmetry Breaking 300
13 2 6 Templating and Masking 302
13 2 7 Hybridization 303
13 3 Nanoinlegrated Systems 304
13 4 Summary and Future Issues 308
References 308
14 NANODEVICES AND NANOMACHINES 311
14 1 General Scheme of Nanodevices 312
14 2 Nanocomponents: Building Units for Nanodevices 314
14 2 1 Interlocked and Interwinded Molecules 314
14 2 2 DNA 315
14 2 3 Carbon Nanotubes and Fullerenes 315
14 3 Three Element Motions: Force Balance at Work 316
14 4 Unit Operations 317
14 4 1 Gating and Switching 318
14 4 2 Directional Rotation and Oscillation 319
14 4 3 Shafting, Shuttling, and Elevatoring 320
14 4 4 Contraction-and-Extension 321
14 4 5 Walking 322
14 4 6 Tweezering or Fingering 323
14 4 7 Rolling and Bearing 323
14 4 8 Pistoning, Sliding, or Conveyoring 324
14 4 9 Self-Directional Movement 324
14 4 10 Capture-and-Release 325
14 4 11 Sensoring 325
14 4 12 Directional Flow 326
14 5 Nanodevices: Fabricated Nanocomponents to Operate 326
14 5 1 Delivery Systems 327
14 5 2 Nanoelectronics 329
XIV
CONTENTS
14 6 Nanomachines: Integrated Nanodevices to Work
14 6 1 Power Source 330
14 6 2 Synchronization 330
14 6 3 Packing 331
14 6 4 Communication with the Macroworld 331
14 7 Summary and Future Issues 331
References 332
|
adam_txt |
SELF-ASSEMBLY AND
NANOTECHNOLOGY
A Force Balance
Approach
Yoon S Lee
Scientific Information Analyst
Chemical Abstracts Service
A Division of the American Chemical Society
Columbus, Ohio
WILEY
A JOHN WILEY amp; SONS, INC , PUBLICATION
CONTENTS
Preface and Acknowledgments xv
PART I SELF-ASSEMBLY 1
1 UNIFIED APPROACH TO SELF-ASSEMBLY 3
1 1 Self-Assembly through Force Balance 5
1 2 General Scheme for the Formation of Self-Assembled
Aggregates 8
1 3 General Scheme for Self-Assembly Process 10
1 4 Concluding Remarks 17
References 18
2 INTERMOLECULAR AND COLLOIDAL FORCES 21
2 1 Van der Waals Force 22
2 2 Electrostatic Force: Electric Double-Layer 28
2 3 Steric and Depletion Forces 33
2 4 Solvation and Hydration Forces 37
241 Solvation Force 37
242 Hydration Force 38
2 5 Hydrophobic Effect 39
2 6 Hydrogen Bond 42
References 44
3 MOLECULAR SELF-ASSEMBLY IN SOLUTION I: MICELLES 47
3 1 Surfactants and Micelles 48
3 2 Physical Properties of Micelles 50
321 Micellization 50
322 Critical Micellar Concentration and Aggregation
Number 51
323 Counterion Binding 53
vii
CONTENTS
viii
3 3 Thermodynamics of Micellization 53
331 Mass-Action Model 54
332 Pseudo-phase Separation Model 55
333 Hydrophobie Effect and Enthalpy-Entropy
Compensation 57
3 4 Micellization versus General Scheme of Self-Assembly 58
341 Change of Micelle Structures 58
342 General Scheme of Micellization 60
343 Concept of Force Balance and Surfactant Packing
Parameter 60
3 5 Multicomponent Micelles 63
3 6 Micellar Solubilization 66
3 7 Applications of Surfactants and Micelles 68
371 Micellar Catalysis 69
References 71
4 MOLECULAR SELF-ASSEMBLY IN SOLUTION II: BILAYERS,
LIQUID CRYSTALS, AND EMULSIONS 75
4 1 Bilayers 76
411 Bilayer-Forming Surfactants 76
412 Bilayerization 77
413 Physical Properties of Bilavers 79
4 2 Vesicles Liposomes, and Niosomes 80
421 Physical Properties of Vesicles 80
422 Micellar Catalysis on Vesicles 82
4 3 Liquid Crystals 83
431 Thermotropic Liquid Crystals 84
432 Lyotropic Liquid Crystals 87
4321 Concentration-Temperature Phase Diagram 87
4322 Ternary Surfactant-Water-Oil (or
Co-surfactant) Phase Diagram 90
4 4 Emulsions 92
441 Microemulsions 93
442 Reverse Micelles 95
443 Macroemulsions 97
444 Micellar Catalysis on Microemulsions 99
References 100
5 COLLOIDAL SELF-ASSEMBLY 103
5 1 Forces Induced by Colloidal Phenomena 104
511 Surface Tension and Capillarity 105
512 Contact Angle and Wetting 108
CONTENTS ix
513 Adhesion 109
514 Gravity and Diffusion 110
515 Pressures by Osmotic and Donnan Effects 112
516 Electrokinetic Force 114
517 Magnetophoretic Force 116
518 Force by Flow 117
5 2 Force Balance for Colloidal Self-Assembly 118
5 3 General Scheme for Colloidal Self-Assembly 120
5 4 Micelle-like Colloidal Self-Assembly: Packing Geometry 121
5 5 Summary 122
References 123
6 SELF-ASSEMBLY AT INTERFACES 125
6 1 General Scheme for Interfacial Self-Assembly 126
611 Surfaces and Interfaces 126
612 Force Balance with Interfaces 127
6 2 Control of Intermolecular Forces at Interfaces 129
621 Packing Geometry: Balance with Attractive and
Repulsive Forces 129
622 Packing with Functional Groups: Balance with
Directional Force 130
6221 Building Units with Multifunctional Sites 130
6222 Building Units with Single Functional Sites 132
623 Packing of Nonamphiphilic Building Units 134
6 3 Self-Assembly at the Gas-Liquid Interface 135
631 Langmuir Monolayer 135
632 Surface Micelles 138
6 4 Self-Assembly at the Liquid-Solid Interface 139
6 5 Self-Assembly at the Liquid-Liquid Interface 140
6 6 Self-Assembly at the Gas-Solid Interface 140
6 7 Interface-Induced Chiral Self-Assembly 142
References 145
7 BIO-MIMETIC SELF-ASSEMBLY 149
7 1 General Picture of Bio-mimetic Self-Assembly 150
7 2 Force Balance Scheme for Bio-mimetic Self-Assembly 153
7 3 Origin of Morphological Chirality and Diversity 155
731 Chirality of Building Units 155
732 Asymmetric Structure of Building Units 157
733 Multiple Hydrogen Bonds 158
734 Cooperative Balance of Geometry and Bonding 159
735 Induced Asymmetric Packing 160
X
CONTENTS
7 4 Symmetric Bio-mimetic Self-Assembled Aggregates 161
741 H-and J-Aggregates 161
742 Molecular Capsules 163
7 5 Gels: Networked Bio-mimetic Self-Assembled Aggregates 163
7 6 Properties of Bio-mimetic Self-Assembled Aggregates 165
761 Directionality Site-Specificity, and Chirality 165
762 Hierarchicality 166
763 Complementarity 167
764 Chiroptical Properties 167
7 7 Future Issues 168
References 168
PART II NANOTECHNOLOGY 171
8 IMPLICATIONS OF SELF-ASSEMBLY FOR NANOTECHNOLOGY 173
8 1 General Concepts and Approach to Nanotechnology 173
8 2 Self-Assembly and Nanotechnology Share the Same Building
Units 176
8 3 Self-Assembly and Nanotechnology Are Governed by
the Same Forces 177
8 4 Self-Assembly versus Manipulation for the Construction of
Nanostructures 177
8 5 Self-Aggregates and Nanotechnology Share the Same
General Assembly Principles 178
8 6 Concluding Remarks 180
References 181
9 NANOSTRUCTURED MATERIALS 183
9 1 What Are Nanostructured Materials? 184
9 2 Intermolecular Forces During the Formation of
Nanostructured Materials 185
9 3 Sol-Gel Chemistry 187
9 4 General Self-Assembly Schemes for the Formation of
Nanostructured Materials 189
9 5 Micro-, Meso-, and Macroporous Materials 190
9 6 Mesostructured and Mesoporous Materials 192
961 Formation of Mesoporous Silica with Hexagonal
Structure 193
962 Structural Control of Mesostructured and Mesoporous
Materials 195
CONTENTS XI
963 Epitaxial Analysis at the Micelle-Silica Interface 198
964 Charge Matching at the Micelle-Silica Interface 203
965 Characterization of Mesostructured and Mesoporous
Materials 204
9 7 Organic-Inorganic Hybrid Mesostructured and Mesoporous
Materials 205
9 8 Microporous and Macroporous Materials 206
981 Co-Self-Assembly for the Formation of Microporous
Materials 207
982 Emulsions for the Formation of Macroporous
Materials 209
983 Colloidal Self-Assembly for the Formation of
Macroporous Materials 210
9 9 Applications of Nanostructured and Nanoporous Materials 211
9 10 Summary and Future Issues 214
References 216
10 NANOPARTICLES: METALS, SEMICONDUCTORS, AND OXIDES 221
10 1 What are Nanoparticles? 222
10 2 Intermolecular Forces During the Synthesis of Nanoparticles 224
10 3 Synthesis of Nanoparticles 226
10 3 1 Direct Synthesis: Confinement-by-Adsorption 227
10 3 2 Synthesis within Preformed Nanospace 229
10 321 Surfactant Self-Assembled Aggregates 230
10 322 Bio-mimetic Self-Assembled Aggregates 232
10 323 Dendritic Polymers 233
10 324 Nanoporous Solids 233
10 325 Directed Growth by Soft Epitaxy 234
10 326 Directed Growth by Hard Epitaxy 234
10 3 3 Nanoparticle Synthesis with Nonconventional Media 236
10 331 Supercritical Fluids 236
10 332 Ionic Liquids 237
10 4 Properties of Nanoparticles 238
10 4 1 Quantum Size Effect 238
10 411 Optical Properties of Semiconductors 238
10 412 Optical Properties of Noble Metals 240
10 413 Electromagnetic Properties of Noble Metals 240
10 414 Electric Properties of Metals 241
10 4 2 Surface Atom Effect 241
10 5 Applications of Nanoparticles 243
10 5 1 Chemical and Biological Sensors 243
10 5 2 Optical Sensors 244
10 5 3 Nanocomposites and Hybrid Materials 245
XII
CONTENTS
10 5 4 Catalysis 245
10 5 5 Functional Fluids 245
10 6 Summary and Future Issues 246
References 247
11 NANOSTRUCTURED FILMS 249
11 1 What Is Nanostructured Film? 249
11 2 General Scheme for Nanostructured Films 251
11 3 Preparation and Structural Control of Nanostructured Films 252
11 3 1 Self-Assembled Monolayer (SAM) 252
11 3 2 Layer-by-Layer Assembly 255
11 3 3 Vapor-Deposited Films 256
11 3 4 Sol-Gel Processed Films 258
11 3 5 Langmuir-Blodgett (LB) Films 259
11 4 Properties and Applications of Nanostructured Films 263
11 4 1 Nanoporous Films 263
11 4 2 Nanolayered Films 263
11 4 3 Nanopatterned Films 264
11 4 4 Monolayer: Model Membrane 265
11 5 Summary and Future Issues 266
References 267
12 NANOASSEMBLY BY EXTERNAL FORCES 271
12 1 Force Balance and the General Scheme of Self-Assembly
Under External Forces 272
12 2 Colloidal Self-Assembly Under External Forces 273
12 2 1 Capillary Force 273
12 2 2 Electric Force 275
12 2 3 Magnetic Force 277
12 2 4 Flow 278
12 2 5 Mechanical Force 279
12 2 6 Force by Spatial Confinement 280
12 2 7 Other Forces 282
12 271 Laser-Optical Force 282
12 272 Ultrasound 282
12 273 Gravity and Centrifugal Forces 282
12 3 Molecular Self-Assembly Under External Forces 283
12 3 1 Flow 283
12 3 2 Magnetic Field 285
12 3 3 Concentration Gradient 285
12 3 4 Confinement 286
12 3 5 Gravity and Centrifugal Forces 287
CONTENTS Xiii
12 4 Applications of Colloidal Aggregates 287
12 4 1 Optical Band Gap 287
12 4 2 Nanostructured Materials 288
12 5 Summary and Future Issues 288
References 290
13 NANOFABRICATION 293
13 1 Self-Assembly and Nanofabrication 294
13 2 Unit Fabrications 296
13 2 1 Jointing 296
13 2 2 Crossing and Curving 297
13 2 3 Alignment and Stacking 298
13 2 4 Reconstruction, Deposition, and Coating 299
13 2 5 Symmetry Breaking 300
13 2 6 Templating and Masking 302
13 2 7 Hybridization 303
13 3 Nanoinlegrated Systems 304
13 4 Summary and Future Issues 308
References 308
14 NANODEVICES AND NANOMACHINES 311
14 1 General Scheme of Nanodevices 312
14 2 Nanocomponents: Building Units for Nanodevices 314
14 2 1 Interlocked and Interwinded Molecules 314
14 2 2 DNA 315
14 2 3 Carbon Nanotubes and Fullerenes 315
14 3 Three Element Motions: Force Balance at Work 316
14 4 Unit Operations 317
14 4 1 Gating and Switching 318
14 4 2 Directional Rotation and Oscillation 319
14 4 3 Shafting, Shuttling, and Elevatoring 320
14 4 4 Contraction-and-Extension 321
14 4 5 Walking 322
14 4 6 Tweezering or Fingering 323
14 4 7 Rolling and Bearing 323
14 4 8 Pistoning, Sliding, or Conveyoring 324
14 4 9 Self-Directional Movement 324
14 4 10 Capture-and-Release 325
14 4 11 Sensoring 325
14 4 12 Directional Flow 326
14 5 Nanodevices: Fabricated Nanocomponents to Operate 326
14 5 1 Delivery Systems 327
14 5 2 Nanoelectronics 329
XIV
CONTENTS
14 6 Nanomachines: Integrated Nanodevices to Work
14 6 1 Power Source 330
14 6 2 Synchronization 330
14 6 3 Packing 331
14 6 4 Communication with the Macroworld 331
14 7 Summary and Future Issues 331
References 332 |
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discipline_str_mv | Chemie / Pharmazie Elektrotechnik / Elektronik / Nachrichtentechnik |
format | Book |
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id | DE-604.BV023475736 |
illustrated | Illustrated |
index_date | 2024-07-02T21:36:04Z |
indexdate | 2024-07-09T21:19:38Z |
institution | BVB |
isbn | 9780470248836 |
language | English |
lccn | 2007052383 |
oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-016657980 |
oclc_num | 187417678 |
open_access_boolean | |
owner | DE-703 DE-20 DE-19 DE-BY-UBM DE-29T |
owner_facet | DE-703 DE-20 DE-19 DE-BY-UBM DE-29T |
physical | XVI, 344 S. Ill., graph. Darst. |
publishDate | 2008 |
publishDateSearch | 2008 |
publishDateSort | 2008 |
publisher | Wiley |
record_format | marc |
spelling | Lee, Yoon Seob Verfasser aut Self-assembly and nanotechnology a force balance approach Yoon S. Lee Hoboken, NJ Wiley 2008 XVI, 344 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Nanostructured materials Design Nanotechnology Self-assembly (Chemistry) Nanotechnologie (DE-588)4327470-5 gnd rswk-swf Selbstorganisation (DE-588)4126830-1 gnd rswk-swf Nanostrukturiertes Material (DE-588)4342626-8 gnd rswk-swf Nanostrukturiertes Material (DE-588)4342626-8 s Selbstorganisation (DE-588)4126830-1 s Nanotechnologie (DE-588)4327470-5 s DE-604 http://www.loc.gov/catdir/enhancements/fy0806/2007052383-d.html Publisher description http://www.loc.gov/catdir/enhancements/fy0829/2007052383-b.html Contributor biographical information HEBIS Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016657980&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
spellingShingle | Lee, Yoon Seob Self-assembly and nanotechnology a force balance approach Nanostructured materials Design Nanotechnology Self-assembly (Chemistry) Nanotechnologie (DE-588)4327470-5 gnd Selbstorganisation (DE-588)4126830-1 gnd Nanostrukturiertes Material (DE-588)4342626-8 gnd |
subject_GND | (DE-588)4327470-5 (DE-588)4126830-1 (DE-588)4342626-8 |
title | Self-assembly and nanotechnology a force balance approach |
title_auth | Self-assembly and nanotechnology a force balance approach |
title_exact_search | Self-assembly and nanotechnology a force balance approach |
title_exact_search_txtP | Self-assembly and nanotechnology a force balance approach |
title_full | Self-assembly and nanotechnology a force balance approach Yoon S. Lee |
title_fullStr | Self-assembly and nanotechnology a force balance approach Yoon S. Lee |
title_full_unstemmed | Self-assembly and nanotechnology a force balance approach Yoon S. Lee |
title_short | Self-assembly and nanotechnology |
title_sort | self assembly and nanotechnology a force balance approach |
title_sub | a force balance approach |
topic | Nanostructured materials Design Nanotechnology Self-assembly (Chemistry) Nanotechnologie (DE-588)4327470-5 gnd Selbstorganisation (DE-588)4126830-1 gnd Nanostrukturiertes Material (DE-588)4342626-8 gnd |
topic_facet | Nanostructured materials Design Nanotechnology Self-assembly (Chemistry) Nanotechnologie Selbstorganisation Nanostrukturiertes Material |
url | http://www.loc.gov/catdir/enhancements/fy0806/2007052383-d.html http://www.loc.gov/catdir/enhancements/fy0829/2007052383-b.html http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016657980&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
work_keys_str_mv | AT leeyoonseob selfassemblyandnanotechnologyaforcebalanceapproach |