vic321try 2006-11-15 13:36
Nanochemistry: A Chemical Approach to Nanomaterials
[URL=http://www.nanost.net/bbs/thread-392-1-1.html][IMG]http://img168.imageshack.us/img168/5416/nanochemistrye4ee33lt6.jpg[/IMG][/URL]
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Source By G Ozin, A Arsenault; University of Toronto, Canada!i�[0l�r&Z&`#c�s/`&z
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ISBN 0 85404 664 X
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Published 26/09/2005
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Format Hardcover�v2_(o�m8o1`.G
Extent xlii+628#h�o0N
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Price £39.95-g�]�@�[�g�G.r�Y
Synopsis�d7~�a�}�d8j:W
International interest in nanoscience research has flourished in recent years, as it becomes an integral part in the development of future technologies. The diverse, interdisciplinary nature of nanoscience means effective communication between disciplines is pivotal in the successful utilization of the science.
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Nanochemistry: A Chemical Approach to Nanomaterials is the first textbook for teaching nanochemistry and adopts an interdisciplinary and comprehensive approach to the subject. It presents a basic chemical strategy for making nanomaterials and describes some of the principles of materials self-assembly over 'all' scales. It demonstrates how nanometre and micrometre scale building blocks (with a wide range of shapes, compositions and surface functionalities) can be coerced through chemistry to organize spontaneously into unprecedented structures, which can serve as tailored functional materials. Suggestions of new ways to tackle research problems and speculations on how to think about assembling the future of nanotechnology are given. :?!F4b+a b�m�C
Primarily designed for teaching, this book will appeal to graduate and advanced undergraduate students. It is well illustrated with graphical representations of the structure and form of nanomaterials and contains problem sets as well as other pedagogical features such as further reading, case studies and a comprehensive bibliography.�\/Y�z0h6\,@6H(}�n
Brief Contents
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Preface - In the Beginning there was Nano; Nanochemistry Basics; Chemical Patterning and Lithography; Layer-By-Layer Self-Assembly; Nanocontact Printing and Writing; Nanorod, Nanotube, Nanowire Self-Assembly; Nanocluster Self-Assembly; Microspheres - Colours from the Beaker; Microporous and Mesoporous Materials; Self-Assembling Block Copolymers; Biomaterials and Bioinspiration; Self-Assembly of Large Building Blocks; Nano and Beyond; Nanochemistry and Nanolabs; Subject Index
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Notes
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Customers who wish to obtain an Adoption Copy of this book in order to assess suitability as a student text should contact the Manager Sales and Customer Service at our Cambridge address. �K#c�z2X�W.Z�w
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[review=nanost-admin]论坛重赏这本书的分享者,提供分享这奖励50金币,2VIP。[/review]�?�W*i1`�}
[url=http://www.rsc.org/images/nano01-9107_tcm18-41242.pdf]http://www.rsc.org/images/nano01-9107_tcm18-41242.pdf[/url]
nanobio 2006-11-16 13:27
好书,不错,�U
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楼主给出下载地址,
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好大家看完了交流啊
nanoquebec 2006-11-30 09:53
Table of Contents
List of Acronyms xxv�g�O�p�H�t�O:g&N1f�^
Teaching (Nano)Materials xxix1x�l)B#]3g
Learning (Nano)Materials xxxi�u�h;F�d,^1a�d
About the Authors xxxiii
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Acknowledgements xxxvii
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Nanofood for Thought - Thinking about Nanochemistry, Nanoscience, Nanotechnology and Nanosafety xxxix�`3u7d e�X�Y
Chapter 1 Nanochemistry Basics 1
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1.1 Materials Self-Assembly 1
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1.2 Big Bang to the Universe 2*A�G
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1.3 Why Nano? 2
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1.4 What do we Mean by Large and Small Nanomaterials? 3
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1.5 Do it Yourself Quantum Mechanics 41R�G8t�T�i'a
1.6 What is Nanochemistry? 5.k�o(t1k#i�{�O�X
1.7 Molecular vs. Materials Self-Assembly 5
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1.8 What is Hierarchical Assembly? 6 R9t�T%N�@6O
1.9 Directing Self-Assembly 6$z!f:Q8H�c7K9O4|
1.10 Supramolecular Vision 7/k�_�@#}:q�q4v#S
1.11 Geneology of Self-Assembling Materials 8
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1.12 Unlocking the Key to Porous Solids 11#@�Y d#f�]�Q�L%t1r(E�}
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1.13 Learning from Biominerals - Form is Function 14
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1.14 Can you Curve a Crystal? 16&q�L�e�y�R/S
1.15 Patterns, Patterns Everywhere 17
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1.16 Synthetic Creations with Natural Form 18
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1.17 Two-Dimensional Assemblies 20
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1.18 SAMs and Soft Lithography 23
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1.19 Clever Clusters 24
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1.20 Extending the Prospects of Nanowires 26*W3J�f�C'v V
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1.21 Coercing Colloids 27�h�o�C�k�a
1.22 Mesoscale Self-Assembly 31�I
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1.23 Materials Self-Assembly of Integrated Systems 32&l3H�{#g�K�]/N�C�O
1.24 References 33
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Nanofood for Thought - Nanochemistry, Genealogy Materials Self-Assembly, Length Scales 45(G1a�?�u,m&R�J�Z�d
Chapter 2 Chemical Patterning and Lithography 49�c#S/w$v.U�f�d�l
2.1 Soft Lithography 49'k:P�w�G)n�^
2.2 What are Self-Assembled Monolayers? 503y�j1Q3J�s/m6S5z
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2.3 The Science and Art of Soft Lithography 52
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2.4 Patterning Wettability? 54 u�b
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2.5 Condensation Figures 55
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2.6 Microlens Arrays 56
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2.7 Nanoring Arrays 583w�t2p�F�`
2.8 Patterning the Solid State 59�M�V/[3v5E9S�t8d
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2.9 Primed for Printing Polymers 61
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2.10 Beyond Molecules - Transfer Printing of Thin Films 63
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2.11 Electrically Contacting SAMS 64�A$N'G�]#P0y�d
2.12 SAM Crystal Engineering 66
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2.13 Learning from Nature's Biocrystal Engineering 68
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2.14 Colloidal Microsphere Patterns 71�y�X�f�Z�S�h
2.15 Switching SAM Function 71�e�T�m�Q!e6x#L�^5s
2.16 Patterning by Photocatalysis 73
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2.17 Reversibly Switching SAMs 74�O:o�J�A3t-T�G�t�n
2.18 Electrowettability Switch 76�h�t�J�h8G)G�\
2.19 Sweet Chips 773g�x U @�F
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2.20 All Fall Down in a Row Lithography 79"p�f2d�`�N%Q s'O)z�X6t
2.21 References 80�k�^�E�G;U0p
Nanofood for Thought - Soft Lithography, SAMs, Patterning 89�M$t%G�X8L�V
Chapter 3 Layer-by-Layer Self-Assembly 95�x�`4f�Y9|�k�z'i
3.1 Building One Layer at a Time 95
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3.2 Electrostatic Superlattices 95;Y9H0]8O,T�B�X�t
3.3 Organic Polyelectrolyte Multilayers 97
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3.4 Layer-by-Layer Smart Windows 97$|;t%L�r�a
3.5 How Thick is Thin? 99�m4}�J,F5]
3.6 Assembling Metallopolymers 990o�`/\�\�|�L�Q8o
3.7 Directly Imaging Polyelectrolyte Multilayers 100
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3.8 Polyelectrolyte-Colloid Multilayers 101�X8r
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3.9 Graded Composition LbL Films 103
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3.10 LbL MEMS 104
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3.11 Trapping Active Proteins 106
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3.12 Layering on Curved Surfaces 106
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3.13 Crystal Engineering of Oriented Zeolite Film 108
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3.14 Zeolite-Ordered Multicrystal Arrays 110
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3.15 Crosslinked Crystal Arrays 111�X,s�b�L�u�\:F6D
3.16 Layering with Topological Complexity 112
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3.17 Patterned Multilayers 113'c
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3.18 Non-Electrostatic Layer-by-Layer Assembly 115
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3.19 Low Pressure Layers 116
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3.20 Layer-by-Layer Self-Limiting Reactions 117
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3.21 References 118
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Nanofood for Thought - Designer Monolayers, Multilayers, Materials Flatland 126([*A�h�J�t,v
Chapter 4 Nanocontact Printing and Writing - Stamps and Tips 131
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4.1 Sub-100 nm Soft Lithography 131
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4.2 Extending Microcontact Printing 131�H%o4y'H�Q
4.3 Putting on the Pressure 133�t�M1F3L(B�o�V#{�Y
4.4 Defect Patterning - Topologically Directed Etching 135
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4.5 Below 50 nm Nanocontact Printing 1366a7\�\*K7V
4.6 Nanocontact Writing - Dip Pen Nanolithography 137
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4.7 DPN of Silicon 138
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4.8 DPN on Glass 139�T�q�J+u)F�J
4.9 Nanoscale Writing on Seminconductor Nanowires 140
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4.10 Sol-Gel DPN 1410~�c�O(^ F�q
4.11 Soft Patterning of Hard Magnets 142
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4.12 Writing Molecular Recognition 1437?�t9v�R�v
4.13 DPN Writing Protein Recognition Nanostructures 145
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4.14 Patterning Bioconstructions 145
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4.15 Eating Patterns - Enzyme DPN 147
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4.16 Electrostatic DPN 148
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4.17 Electrochemical DPN 148
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4.18 SPM Nano-Electrochemistry 149%n�Y O�i�J�I�M$P
4.19 Beyond DPN - Whittling Nanostructures 151
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4.20 Combi Nano - DPN Combinatorial Libraries 1510Q�p�N"[+{
4.21 Nanoplotters 153-_�]�u�k�r�t�}�R�@
4.22 Nanoblotters 154�J�n-K9b�a�_�w�T
4.23 Scanning Probe Contact Printing (SP-CP) 155�f�j#`�g,V�T�y�A)S
4.24 Dip Pen Nanolithography Stamp Tip - Beyond DPN CP 157�E.C#f�r0w0X-^+v
4.25 Best of Both Worlds 157)?:h&X�e.d8[�`�U
4.26 The Nanogenie is out of the Bottle 158$A4e�n6L*R/i�k�s�G
4.27 References 1584[&L8u�T�k6r�f�B
Nanofood for Thought - Sharper Chemical Patterning Tools 164�x"R2^�I"S
Chapter 5 Nanorod, Nanotube, Nanowire Self-Assembly 167�P�H�s�R9k+Y
5.1 Building Block Assembly 167
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5.2 Templating Nanowires 167
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5.3 Modulated Diameter Gold Nanorods 168
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5.4 Modulated Composition Nanorods 170�J�@
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5.5 Barcoded Nanorod Orthogonal Self-Assembly 1738b
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5.6 Self-Assembling Nanorods 1766e"D�_-f�l%j)|�G�{
5.7 Magnetic Nanorods Bunch Up 177�x�h*W�Q1];r
5.8 Magnetic Nanorods and Magnetic Nanoclusters 178
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5.9 An Irresistable Attraction for Biomolecules 181
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5.10 Hierarchically Ordered Nanorods 183
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5.11 Nanorod Devices 184
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5.12 Nanotubes from Nanoporous Templates 186/D3m-z�e�G�u
5.13 Layer-by-Layer Nanotubes from Nanorods 188
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5.14 Synthesis of Single Crystal Semiconductor Nanowires 189
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5.15 Vapor-Liquid-Solid Synthesis of Nanowires 189
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5.16 What Controls Nanowire-Oriented Growth? 191�i!M8t�_�K�G v-M4Y�]
5.17 Supercritical Fluid-Liquid-Solid Synthesis 1910P�_/j5E�l�[4L�Q�{
5.18 Nanowire Quantum Size Effects 193�k�A�h�F�X9M�O�M
5.19 Zoo of Nanowire Compositions and Architectures 195
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5.20 Single-Source Precursors 195
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5.21 Manipulating Nanowires 196
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5.22 Crossed Semiconductor Nanowires - Smallest LED 199
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5.23 Nanowire Diodes and Transistors 201'K(c#p*a;U�[�E�l
5.24 Nanowire Sensors 201'b,b,`�B�I�s�c!i-O�o�O�b
5.25 Catalytic Nanowire Electronics 203
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5.26 Nanowire Heterostructures 204
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5.27 Longitudinal Nanowire Superlattices 2061G�g�l�w)`�h
5.28 Axial Nanowire Heterostructures 207
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5.29 Nanowires Branch Out 209
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5.30 Coaxially Gated Nanowire Transistor 209
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5.31 Vertical Nanowire Field Effect Transistors 212�E�d�e�s
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5.32 Integrated Metal-Semiconductor Nanowires - Nanoscale Electrical Contacts 215�i�C(E i r/L$O
5.33 Photon-Driven Nanowire Laser 216�T&_�~�e�E:L){�\�\.F
5.34 Electrically Driven Nanowire Laser 218-F;P�~3[!o�G/a�N�E0E
5.35 Nanowire UV Photodetectors 220
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5.36 Simplifying Complex Nanowires 220
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5.37 Nanowire Casting of Single-Crystal Nanotubes 222
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5.38 Solution-Phase Routes to Nanowires 223
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5.39 Spinning Nanowire Devices 226�G*q5m+k�v-x3i�Y�h
5.40 Hollow Nanofibers by Electrospinning 227
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5.41 Carbon Nanotubes 229�t�r�Z A%q:N�p�J
5.42 Carbon Nanotube Structure and Electrical Properties 229
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5.43 Gone Ballistic 231
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5.44 Carbon Nanotube Nanomechanics 233�X;s0E0p3?�E/F�b
5.45 Carbon Nanotube Chemistry 233�Q�R/D�l�C"c�k
5.46 Carbon Nanotubes All in a Row 2366o!{'^(F�n
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5.47 Carbon Nanotube Photonic Crystal 238
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5.48 Putting Carbon Nanotubes Exactly Where You Want Them 240
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5.49 The Nanowire Pitch Challenge 242
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5.50 Integrated Nanowire Nanoelectronics 244-L�B�H�{�U#Q�P�d&D,O�w"e
5.51 A Small Thought at the End of a Large Chapter 246
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5.52 References 246*p%\'H�t�u�r-v/r
Nanofood for Thought - Wires, Rods, Tubes, Low Dimensionality 2601|�A�H4~�W�L
Chapter 6 Nanocluster Self-Assembly 265
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6.1 Building-Block Assembly 265
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6.2 When is a Nanocluster a Nanocrystal or Nanoparticle? 266;Q�u�W�g�V%M(l
6.3 Synthesis of Capped Semiconductor Nanoclusters 266
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6.4 Electrons and Holes in Nanocluster Boxes 268'S:_�Y(R%P�L�v
6.5 Watching Nanoclusters Grow 270
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6.6 Nanocrystals in Nanobeakers 271
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6.7 Nanocluster Semiconductor Alloys and Beyond 273
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6.8 Nanocluster Phase Transformation 274�a
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6.9 Capped Gold Nanoclusters - Nanonugget Rush 275�L�o0l�D S.u�z�[6v*]
6.10 Alkanethiolate Capped Nanocluster Diagnostics 277�A%J+k/{3Q,F�}�z�]
6.11 Periodic Table of Capped Nanoclusters 278�h�t�C�b�e�z
6.12 There's Gold in Them Thar Hills! 278
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6.13 Water-Soluble Nanoclusters 279,z)W8T8B)q�i2h
6.14 Capped Nanocluster Architectures and Morphologies 281
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6.15 Alkanethiolate Capped Silver Nanocluster Superlattice 282
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6.16 Crystals of Nanocrystals 284
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6.17 Beyond Crystal of Nanocrystals - Binary Nanocrystal Superlattices 285#A�\�^+e�o�U,v�]
6.18 Capped Magnetic Nanocluster Superlattice - High Density Data Storage Materials 286
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6.19 Alloying Core-Shell Magnetic Nanoclusters 287&?�k5Z'x:D�z'@6^�}�N
6.20 Soft Lithography of Capped Nanoclusters 288�w�@�Z�Z%m/`�`,^9i
6.21 Organizing Nanoclusters by Evaporation 289
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6.22 Electroluminescent Semiconductor Nanoclusters 289
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6.23 Full Color Nanocluster-Polymer Composites 291
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6.24 Capped Semiconductor Nanocluster Meets Biomolecule 293
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6.25 Nanocluster DNA Sensors - Besting the Best 296�p,W.Q#\5a+D�{�k
6.26 Semiconductor Nanoclusters Extend and Branch Out 297
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6.27 Branched Nanocluster Solar Cells 299
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6.28 Tetrapod of Tetrapods - Towards Inorganic Dendrimers 300�O2t�Z/z%E�?;E�A
6.29 Golden Tips - Making Contact with Nanorods 301
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6.30 Flipping a Nanocluster Switch 303)f(k&s�~�C
6.31 Photochromic Metal Nanoclusters 304�g�t�h�D�y+_*g�G�B�[
6.32 Carbon Nanoclusters - Buckyballs 3068W
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6.33 Building Nanodevices with Buckyballs 3077a�U�}/{�O$b y
6.34 Carbon Catalysis with Buckyball 308�s�y�`�`�P*S8|
6.35 References 309
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Nanofood for Thought - Nanoclusters, Nanocrystals, Quantum Dots, Quantum Size Effects 320�u�Q�O4{ h:Z'R&C
Chapter 7 Microspheres - Colors from the Beaker 325
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7.1 Nature's Photonic Crystals 325
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7.2 Photonic Crystals 325
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7.3 Photonic Semiconductors 327
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7.4 Defects, Defects, Defects 328�i$g
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7.5 Computing with Light 328�U�]!Z�K+Z�N&{
7.6 Color Tunability 330%}�s
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7.7 Transferring Nature's Photonic Crystal Technology to the Chemistry Laboratory 330
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7.8 Microsphere Building Blocks 331
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7.9 Silica Microspheres 331
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7.10 Latex Microspheres 332
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7.11 Multi-Shell Microspheres 332
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7.12 Basics of Microsphere Self-Assembly 333�R�z6N"n�b�P�M�]�H
7.13 Microsphere Self-Assembly - Crystals and Films 3341],i#q�O,u(w
7.14 Colloidal Crystalline Fluids 336�i�s�{�m�e'L2h-e
7.15 Beyond Face Centered Cubic Packing of Microspheres 337�X _ I:f�s$_�N�s
7.16 Templates - Confinement and Epitaxy 338�Y�c/c#J"{.a-{
7.17 Photonic Crystal Fibers 340
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7.18 Photonic Crystal Marbles 340
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7.19 Optical Properties of Colloidal Crystals - Combined Bragg-Snell Laws 343
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7.20 Basic Optical Properties of Colloidal Crystals 343 w(S;O�~�\�V5{,U8\
7.21 How Perfect is Perfect? 345
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7.22 Cracking Controversy 346
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7.23 Synthesizing a Full Photonic Band Gap 3481v�a�L�A!q9X
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7.24 Writing Defects 349
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7.25 Getting Smart with Planar Defects 350�I�}�}�]6|
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7.26 Switching Light with Light 353/y7@�z�u"H9Z�S$K4})|
7.27 Internal Light Sources 353�V:K'A�\(W�P�h1i
7.28 Photonic Inks 354"e#B7s
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7.29 Color Oscillator 357
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7.30 Photonic Crystal Sensors 357
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7.31 Colloidal Photonic Crystal Solar Cell 359
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7.32 Thermochromic Colloidal Photonic Crystal Switch 360
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7.33 Liquid Crystal Photonic Crystal 361
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7.34 Encrypted Colloidal Crystals 363
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7.35 Gazing into the Photonic Crystal Ball 3659n�I4h0K.g�M�{
7.36 References 365
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Nanofood for Thought - Colloidal Assembly, Colloidal Crystals, Colloidal Crystal Devices, Structural Color 373
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Chapter 8 Microporous and Mesoporous Materials from Soft Building Blocks 379
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8.1 Escape from the Zeolite Prison 379
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8.2 A Periodic Table of Materials Filled with Holes 3809v�a�q,T�r#m�f�[
8.3 Modular Self-Assembly of Microporous Materials 381�]8q�I�x�v�Q�n�o&u�W
8.4 Hydrogen Storage Coordination Frameworks 383+\�?!L:?�t�l�u&c'N
8.5 Overview and Prospects of Microporous Materials 384
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8.6 Mesoscale Soft Building Blocks 385"C�z�P
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8.7 Micelle Versus Liquid Crystal Templating Paradox 387
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8.8 Designing Function into Mesoporous Materials 387
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8.9 Tuning Length Scales 388
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8.10 Mesostructure and Dimensionality 3901m�P"S1d n�a%}
8.11 Mesocomposition - Nature of Precursors 390
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8.12 Mesotexture 3917u�^�x
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8.13 Periodic Mesoporous Silica-Polymer Hybrids 392�P&Q1j�A)d$k,z�y s
8.14 Guests in Mesopores 393;Q�k�J�N%j5B�O*D*{9l
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8.15 Capped Nanocluster Meets Surfactant Mesophase 3941[/y�e:}�T
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8.16 Marking Time in Mesostructured Silica - New Approach to Optical Data Storage 396
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8.17 Sidearm Mesofunctionalization 397
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8.18 Organics in the Backbone 398
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8.19 Mesomorphology - Films, Interfaces, Mesoepitaxy 400#U,L'_�q2G#o5{�H;U�f�v
8.20 Stand Up and Be Counted 402
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8.21 Mesomorphology - Spheres, Other Shapes 404
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8.22 Mesomorphology - Patterned Films, Soft Lithography, Micromolding 406
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8.23 Mesomorphology - Morphosynthesis of Curved Form 408�s/D4L:V!k�H�t�n
8.24 Chiral Surfactant Micelles - Chiral Mesoporous Silica 410
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8.25 Mesopore Replication 413
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8.26 Mesochemistry and Topological Defects 4140o4G�g;T�a�u5f
8.27 Mesochemistry - Synthesis in "Intermediate" Dimensions 415&v�X�E�R#U�F�t
8.28 References 418;N)F
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Nanofood for Thought - Soft Blocks Template Hard Precursors, Holey Materials 430�y�O-s9P0u
Chapter 9 Self-Assembling Block Copolymers 435
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9.1 Polymers, Polymers Everywhere in Nanochemistry 435�B�\
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9.2 Block Copolymer Self-Assembly - Chip Off the Old Block 435
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9.3 Nanostructured Ceramics 437
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9.4 Nano-objects 439
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9.5 Block Copolymer Thin Films 4396|�t�g!z$x�R
9.6 Electrical Ordering 442
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9.7 Spatial Confinement of Block Copolymers 442.Z�v�Y(s�s�`&n�@
9.8 Nanoepitaxy 444
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9.9 Block Copolymer Lithography 444�|:\�L+Z�s#{1[!s+_5D
9.10 Decorating Block Copolymers 446%\4~%B�N�s+{8I�L�a
9.11 A Case of Wettability 447,h�a�U�M1S�u�k�y
9.12 Nanowires from Block Copolymers 449
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9.13 Making Micelles 451
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9.14 Assembling Inorganic Polymers 453
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9.15 Harnessing Rigid Rods 453
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9.16 Supramolecular Assemblies 455�^1w�Z�[�H7o3Z�C0f�l�m
9.17 Supramolecular Mushrooms 456
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9.18 Structural Color from Lightscale Block Copolymers 458
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9.19 Block Copolypeptides 459�}�J*A�`(Y�x&m7m:|�y
9.20 Block Copolymer Biofactories 461
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9.21 References 462
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Nanofood for Thought - Block Copolymer Self-Assembling Nanostructures 4685x�J!]�C9d
Chapter 10 Biomaterials and Bioinspiration 473�I�D�G�y�@$e�o�|/t�J�u
10.1 Nature did it First 473
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10.2 To Mimic or to Use? 474
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10.3 Faux Fossils 475
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10.4 Nature's Siliceous Sculptures 476
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10.5 Ancient to Modern Synthetic Morphology 477�i1w)k+s5e't(P$r�}�l/{ H
10.6 Biomimicry 478
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10.7 Biomineralization and Biomimicry Analogies 479+[%d�]�k6H3Q�e�N�]
10.8 Learning from Nature 481�z:x�@"\�].^
10.9 Viral Cage Directed Synthesis of Nanoclusters 482�Q�S4A&z�~�K
10.10 Viruses that Glitter 483�z/Y/L,K0w*Q)|�j5e
10.11 Polynucleotide Directed Nanocluster Assembly 484�o�k�@�M�n
10.12 DNA Coded Nanocluster Chains 485�Q,h�q&h�v)?�U"w�\1n
10.13 Building with DNA 487�{1h�S0F�Q4@:b)E
10.14 Bacteria Directed Materials Self-Assembly 489!r�Y9k2i�u�A
10.15 Using a Virus that is Benign, to Align 491
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10.16 Magnetic Spider Silk 492
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10.17 Protein S-Layer Masks 493
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10.18 Morphosynthesis - Inorganic Materials with Complex Form 496�`�w'M:\�m/z/z�t&t
10.19 Echinoderm vs. Block Copolymers 498�U*f�]�]�d4x�T
10.20 Fishy Top-Down Photonic Crystals 4995A�~:G.q�U
10.21 Aluminophosphates Shape Up 501$^�f%|*b3o
10.22 Better Bones Through Chemistry 502
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10.23 Mineralizing Nanofibers 504
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10.24 Biological Lessons in Materials Design 505
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10.25 Surface Binding Through Directed Evolution 505
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10.26 Nanowire Evolution 5082q�C�a$P,j�p�U
10.27 Biomolecular Motors - Nanomachines Everywhere 508&b)Y0Q�u$~
10.28 How Biomotors Work 510 U*@5A�k�A+Q
10.29 Kinesin - Walk Along 512
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10.30 ATPase - Biomotor Nanopropellors 515,e o�n9I-^�e�l
10.31 (Bio)Inspiration 5160c9q$W�z�_
10.32 References 517$}2N�b�`�K�^�d
Nanofood for Thought - Organic Matrix, Biomineralization, Biomimetics, Bioinspiration 527
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Chapter 11 Self-Assembly of Large Building Blocks 531
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11.1 Self-assembling Supra-micron Shapes 531
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11.2 Synthesis Using the "Capillary Bond" 532�n7~7~'p�c ~$_�x
11.3 Crystallizing Large Polyhedral-Shaped Building Blocks 5332m2C3D�]�B�t�f�G�M.n
11.4 Self-Assembling 2D and 3D Electrical Circuits and Devices 533
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11.5 Crystallizing Micron-Sized Planar Building Blocks 534%o�S%m#}�?1O1_"t
11.6 Polyhedra with Patterned Faces that Autoconstruct 536�U�I�F�C�D�S�T�K+b�L(H
11.7 Large Sphere Building Blocks Self-Assemble into 3D Crystals 540
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11.8 Synthetic MEMS? 541�D
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11.9 Magnetic Self-Assembly 541 q�G�g
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11.10 Dynamic Self-Assembly 543
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11.11 Autonomous Self-Assembly 544�a&? Y$\�C:^
11.12 Self-Assembly and Synthetic Life 547
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11.13 References 548
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Nanofood for Thought - Static and Dynamic, Capillary Bond, Shape Assembly 550
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Chapter 12 Nano and Beyond 553$A�H�R�a�^�q/n'P�^
12.1 Assembling the Future 553
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12.2 Microfluidic Computing 554
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12.3 Fuel Cells - Hold the Membrane 554
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12.4 Curved Prints 554
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12.5 Beating the Ink Diffusion Dilemma 555�L1{�J1|�g�j
12.6 Tip of the Pyramid 5560R9B�t�l*t�P2M0B'i�R
12.7 Biosensing Membranes 556�W�C�k'd�l�E�@3_(s
12.8 Crossing Nanowires 556
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12.9 Complete Crystallographic Control 557
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12.10 Down to the Wire 557:n�U%}�e/d5B&e�|1N
12.11 Shielded Nanowires 558
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12.12 Writing 3D Nanofluidic and Nanophotonic Networks 559
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12.13 Break-and-Glue Transistor Assembly 560�F�H�a%p'b&k)R
12.14 Turning Nanostructures Inside-out 560
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12.15 Confining Spheres 560�^�\ J�@�p9N7Z%a!u�x4i�g
12.16 Escape from the Silica and Polystyrene Prison 562
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12.17 Smart Dust 562
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12.18 Light Writing for Light Guiding 562
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12.19 Nanoring Around the Collar 563�Z�\�^1f�c
12.20 A Meso Rubbed Right 563�j�n�J;a�Z�P
12.21 Fungus with the Midas Touch 564
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12.22 Self-assembled Electronics 565
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12.23 Gears Sink Their Teeth into the Interface 565
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12.24 Materials Retro-assembly 566
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12.25 Matter that Matters - Materials of the "Next Kind" 568
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12.26 References 571
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Nanofood for Thought - Nano Potpourri 574
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Chapter 13 Nanochemistry Nanolabs 579
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Appendix A Origin of the Term "Self-Assembly" 585
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Appendix B Cytotoxicity of Nanoparticles 589
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Appendix C Walking Macromolecules Through Colloidal Crystals 593
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Appendix D Patterning Nanochannel Alumina Membranes With Single Channel Resolution 597�w�_
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Appendix E Muscle Powered Nanomachines 599"M�E!D&Z.Y�d
Appendix F Bacteria Power 603�P3E�i(H#R�X+\"k6_�I
Appendix G Chemically Driven Nanorod Motors 607
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Subject Index
jwucn 2006-12-10 18:54
提供下载地址如下(转贴,来自小木虫)
[url]http://emuch.net/bbs/viewthread.php?tid=367959&fpage=1[/url]+Q&a�y�N:K%U�g�w-H
%Z�c�U�g�D/F�d
[[i] 本帖最后由 jwucn 于 2006-12-10 19:58 编辑 [/i]]
guojjun 2006-12-11 17:34
[quote]原帖由 [i]jwucn[/i] 于 2006-12-10 18:54 发表
(V�u$z(s�@
[url]http://emuch.net/bbs/viewthread.php?tid=367959&fpage=1[/url] [/quote]
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:) 上面已经有了!!!1
zhangdelin0000 2006-12-11 18:08
楼主,能否提供全文内容呢,这只有第一章,谢谢!!!!
cdse 2006-12-28 23:14
a very useful book. Who can provide full text link? Thanks in advanced
nanoworker 2007-05-07 22:17
好哇!可惜只有第一章的内容!要是有全文就好了!期待着这本书早日被nanost收录!
gothljn 2007-05-26 08:42
这的确是一本很好的纳米教科书,在北大图书馆有一本,大家有条件的可以借来看7Z�O�r;|�l�[�c�v
个人看了,非常喜欢这本书
a_stranger 2007-08-21 01:59
A good book!
nanost-admin 2008-05-26 19:08
继续期待和等待之中!可以考虑增加的悬赏!:handshake :time: :lol
hjlyyc 2008-07-25 17:10
这本书书是否权限要求很高啊,检索高手们搞定它!:victory:
nano-st 2008-09-17 16:26
[url]http://www.baydownloads.com/search.php?a=smartteam&q=nanochemistry+a+chemical+approach+to+nanomaterials[/url](x�J�?"E�v�Z�y�l
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[url]http://rapidlibrary.com/index.php?q=nanochemistry+a+chemical+approach+to+nanomaterials&filetype=0[/url]
gengxin60 2008-09-19 11:06
:lol ,good�^ |�H+Z�G/y8v(J�V0U
能否传到网盘上
nanochip 2008-09-20 10:08
:good1 :victory: :hot1 帮顶