Introduction to Nanotechnology

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CANTILEVER \ \ \ \ 13.3. MOLECULAR AND SUPRAMOLECULAR SWITCHES 345 \ \ CARBON NANOTUBE Figure 13.10. Illustration of a single-walled carbon nanotube mounted on an STM tip attached to a cantilever arm of an atomic force microscope. [Adapted from H. Dai et al., Nature 384, 147 (1996).] break. The MWNT tip can also be used in the tapping mode. When the nanotube bends on impact, there is a coherent deexcitation of the cantilever oscillation. The MWNT serves as a compliant spring, which moderates the impact of each tap on the surface. Because of the small cross section of the tip, it can reach into deep trenches on the surface that are inaccessible to normal tips. Since the MWNTs are electrically conducting, they may also be used as probes for an STM. The azobenzene molecule, shown in Fig. 13.1 1 a, can change from the trans isomer to the cis isomer by subjecting it to 3 13-nm light. Isomers are molecules having the same kind of atoms and the same number of bonds but a different equilibrium geometry. Subjecting the cis isomer to light of wavelength greater than 380 nm causes the cis form to return to the original trans form. The two forms can be distinguished by their different optical absorption spectra. Notice that the cis isomer is shorter than the trans isomer. Azobenzene can also form a polymer consisting of a chain of azobenzene molecules. In the polymer form it can also undergo the trans-to-cis transformation by exposure to 365-nm light. When this occurs, the length of the polymer chain decreases. A group at the University of Munich have constructed a molecular machine based on the photoisomerization of the azobenzene polymer. They attached the trans form of the polymer to the cantilever of an atomic force microscope as shown in Fig. 13.11b and then subjected it to light of 365-nm wavelength, causing the polymer to contract and the beam to bend. Exposure to 420-nm light causes the polymer to return to the trans form, allowing the beam to return to its original position. By alternately exposing the polymer to pulses of 420- and 365-nm light, the beam could be made to oscillate. This is the first demonstration of an artificial single-molecule machine that converts light energy to physical work. 13.3. MOLECULAR AND SUPRAMOLECULAR SWITCHES The lithographic techniques used to make silicon chips for computers are approach- ing their limits in reducing the sizes of circuitry on chips. Nanosize architecture is
346 NANOMACHINES AND NANODEVICES 313 nm ____t -.+------- > 380 nm TRANS ISOMER - (a) 365 nm light - 420 nm light (b) 1 N=N CIS ISOMER Figure 13.1 1. (a) Cis-to-trans UV-light-induced isomerization of azobenzene; (b) a molecular machine based on light-induced isomeric changes of the azobenzene polymer, which contracts when it is converted to the cis form, causing the cantilever beam to bend. becoming more difficult and more expensive to make. This has motivated an effort to synthesize molecules, which display switching behavior. This behavior might form the basis for information storage and logic circuitry in computers using binary systems. A molecule A that can exist in two different states, such as two different conformations A and B, and can be converted reversibly between the two states by external stimuli, such as light or a voltage, can be used to store information. In order for the molecule to be used as a zero or one digital state, necessary for binary logic, the change between the states must be fast and reversible by external stimuli. The two states must be thermally stable and be able to switch back and forth many times. Furthermore the two states must be distinguishable by some probe, and the application of the probe R is called the read mode. Figure 13.12 is a schematic A-B SZ s1 and sz= External Stimuli ] 1 A =state o B = state 1 I Figure 13.12. Schematic representation of the elements of a molecular switch. An external stimulus SI changes a molecule from state 0 to state 1, and S, returns the molecule to state 0.
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INTRODUCTION TO NANOTECHNOLOGY Char
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CONTENTS Preface xi 1 Introduction
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5.2 Carbon Molecules 103 5.2.1 Natu
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9.4 Excitons 244 9.5 Single-Electro
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PREFACE In recent years nanotechnol
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INTRODUCTION The prefix nano in the
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INTRODUCTION 3 he recognized the ex
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1000 (I) a 900 4 800 a 900 I 6 700
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INTRODUCTION 7 developed before the
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2.1. STRUCTURE 9 mechanics, the res
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X T 2.1. STRUCTURE 11 Figure 2.4. C
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2.1. STRUCTURE 13 Figure 2.6. Thirt
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Sodium Nanoparticle Na, Magic Numbe
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2.1. STRUCTURE 17 of the large anio
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2.1. STRUCTURE 19 other, and high-f
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2.2. ENERGY BANDS 21 Conduction Ban
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2.2. ENERGY BANDS 23 Figure 2.13. S
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2.2. ENERGYBANDS 25 band at point T
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A X ' Wavevector A Si c z 2.2. ENER
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2.2. ENERGY BANDS 29 bands of Figs.
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2.3. LOCALIZED PARTICLES 31 add ele
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1 meV 10 meV 100 meV FJ E W 1 eV 10
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3 METHODS OF MEASURING PROPERTIES 3
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3.2. STRUCTURE 37 Table 3.1. Crysta
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3.2. STRUCTURE 39 Figure 3.2. Two-d
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3.2. STRUCTURE 41 The widths of the
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44 METHODS OF MEASURING PROPERTIES
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3.3. MICROSCOPY 51 types of transit
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3.3. MICROSCOPY 53 Actual diverging
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Tunneling current Tunneling current
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3.3. MrCAOSCOPY 57 and the latter m
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3.4. SPECTROSCOPY 59 From Eq. (3.8)
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1 Average Panicle FWHM Size (nm) in
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CdSe colloidal NCs a = 1.2 nrn 3.4.
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El X-RAY TUBE 8000 - A 6000 - 4000
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2 N I w 3.0 2.5 2.0 1.5 1 .o 0.5 3.
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i 3.4. SPECTROSCOPY 69 NMR involves
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T=220K - 2G H FURTHER READING 71 Fi
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NUMBER OF ATOMS RADIUS (nm) 1 10 1
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I L 7 3 5 7 9 11 13 15 17 NUMBER OF
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JELLIUM MODEL OF CLUSTERS ATOMS CLU
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1.02 { 1.01 - 1 - 0.99 - 4.2. METAL
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4.2. METAL NANOCLUSTERS 81 Figure 4
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4.2. METAL NANOCLUSTERS 83 Figure 4
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-0 100 200 300 400 500 600 MASSICHA
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a 42. METAL NANOCLUSTERS 87 Figure
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. . . .. . - . D 111111111111111111
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3 4 2.5 0 cn g 2 0 z d 1.5 t a 9 1
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4.3. SEMICONDUCTING NANOPARTICLES 9
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4.4. RARE GAS AND MOLECULAR CLUSTER
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4.5. METHODS OF SYNTHESIS 97 d Figu
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4.5. METHODS OF SYNTHESIS 99 isopro
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PULSED LASER BEAM 1 1 1 1 1 I ROTAT
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5.1. INTRODUCTION CARBON NANOSTRUCT
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5.2. CARBON MOLECULES 105 methane d
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5.3. CARBON CLUSTERS 107 -0 20 40 6
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PHOTON ENERGY (electron volts) 5.3.
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Figure 5.6. Structure of the CEO fu
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1 30 0 14.1 14.2 14.3 14.4 14.5 LAT
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(c) 5.4. CARBON NANOTUBES 115 Figur
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5.4. CARBON NANOTUBES 1 17 The mech
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5.4. CARBON NANOTUBES 11 9 investig
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5.4. CARBON NANOTUBES 121 energy gr
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5.4. CARBON NANOTUBES 123 stretch c
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5.5. APPLICATIONS OF CARBON NANOTUB
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- v) 450 : 400 3 350 1 300 : 5 250
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BULK NANOSTRUCTURED MATERIALS In th
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h 8 0 6.1. SOLID DISORDERED NANOSTR
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6.1. SOLID DISORDERED NANOSTRUCTURE
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6.2. NANOSTRUCTURED CRYSTALS 153 qu
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6.2. NANOSTRUCTURED CRYSTALS 155 Fi
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158 BULK NANOSTRUCTURED MATERIALS 6
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160 BULK NANOSTRUCTURED MATERIALS w
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162 BULK NANOSTRUCTURED MATERIALS 0
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164 BULK NANOSTRUCTURED MATERIALS n
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166 NANOSTRUCTURED FERROMAGNETISM f
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168 NANOSTRUCTURED FERROMAGNETISM i
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170 NANOSTRUCTURED FERROMAGNETISM M
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172 NANOSTRUCTURED FERROMAGNETISM h
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174 NANOSTRUCTURED FERROMAGNETISM d
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176 NANOSTRUCTURED FERROMAGNETISM o
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4 h $ 3 7.5. NANOCARBON FERROMAGNET
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7.6. GIANT AND COLOSSAL MAGNETORESI
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1.4 N 1 1.2 z " 1 0 v 5 h 0.8 0 0.6
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7.6. GIANT AND COLOSSAL MAGNETORESI
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7.7. FERROFLUIDS 187 Figure 7.22. M
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7.7. FECIROFLUIDS 189 Figure 7.25.
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7.7. FERRQFLUlOS 191 FerroRuids can
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FURTHER READING FURTHER READING 193
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10- IR f IA -1 8.1. INTRODUCTION 19
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8.2. INFRARED FREQUENCY RANGE 197 1
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8.2. INFRARED FREQUENCY RANGE 199 d
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s C CTI e 8 9 4( 8.2. INFRARED FREQ
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8.2.3. Raman Spectroscopy 8.2. INFR
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8.2. INFRARED FREQUENCY RANGE 205 a
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- r I 520 51 8 v 6 516 a" 51 4 51 2
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8.2. INFRARED FREQUENCY RANGE 209 i
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v) - C 3 8 600 400 100 0 e e 10 20
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i E (cm-’ ) 20 c I 1 ID 0 4x107 8
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- ? m v .- - z In C a, c C - .. . .
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Excitatior I [eV]: 2.175 2.214 2.25
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6 100 200 300 Time (ns) 8.3. LUMINE
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400 nm Laser / Free excitons Trappe
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8.4. NANOSTRUCTURES IN ZEOLITE CAGE
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FURTHER READING 225 P. Milani and C
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9.2. PREPARATION OF QUANTUM NANOSTR
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i 9.2. PREPARATION OF QUANTUM NANOS
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9.3. SIZE AND DIMENSIONALITY EFFECT
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w n 3 2 1 9.3. SIZE AND DIMENSIONAL
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WE) Quantum Dot Number of Electrons
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9.5. SINGLE-ELECTRON TUNNELING 245
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9.5. SINGLE-ELECTRON TUNNELING 247
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1 pair section ;- COT. .; . . I. .
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o.6 LWIR: T = 77 K 45" incidence AD
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9.7. SUPERCONDUCTIVITY 253 horizont
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9.7. SUPERCONDUCTIVITY 255 applied
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10.1. SELF-ASSEMBLY 10 SELF-ASSEMBL
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10.1. SELF-ASSEMBLY 259 factor of 2
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(a) (LI (dl 10.1. SELF-ASSEMBLY 261
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10.1. SELF-ASSEMBLY 263 atoms, as n
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- c v) ._ C 3 2 9 40 c - .- e m v w
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10.2. CATALYSIS 267 where the lengt
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10.2. CATALYSIS 269 are also other
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1600 2 1200 t p - Bi2M020, 10.2. CA
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7 - I 2,330 m .- c r 0 2 2,300 - u)
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10.2. CATALYSIS 275 with a top and
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10.2. CATALYSIS 277 based on the pr
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10.2. CATALYSIS 279 CnHlnfl, which
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I1 ORGANIC COMPOUNDS AND POLYMERS 1
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11.2. FORMING AND CHARACTERIZING PO
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1 1.3. NANOCRYSTALS 285 This expres
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-1 5 0) C a, -1 1 000 300 100 30 10
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11.3. NANOCRYSTALS 289 Table 11.1.
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11.3. NANOCRYSTALS 291 R’ groups
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11.4. POLYMERS 293 Figure 11.9. Ske
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Page 318 and 319: BiodegradaWe surface 4 Functional g
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Page 365 and 366: 354 NANOMACHINES AND NANODEVICES -1
Page 368 and 369: A.l. INTRODUCTION APPENDIX A FORMUL
Page 370 and 371: A.3. PARTIAL CONFINEMENT 359 limiti
Page 372 and 373: APPENDIX B TABULATIONS OF SEMICONDU
Page 374 and 375: TABULATIONS OF SEMICONDUCTING MATER
Page 376 and 377: Table B.8. Effective masses m+ rela
Page 378 and 379: TABULATIONS OF SEMICONDUCTING MATER
Page 380: TABULATIONS OF SEMICONDUCTING MATER
Page 383 and 384: 372 INDEX amoeba, 3 16 amphiphilic,
Page 385 and 386: 374 INDEX CdS, 9, 130, 213, 216, 36
Page 387 and 388: 376 INDEX dispersion, 277 disulfide
Page 389 and 390: 378 INDEX Ga (gallium) (continued)
Page 391 and 392: 380 INDEX length (continued) critic
Page 393 and 394: 382 INDEX multiple ionization, 93 r
Page 395 and 396: 384 INDEX pi-conjugation, 282, 292
Page 397 and 398: silica, 269 silica-alumina, 269, 27
Page 399: 388 INDEX wavefimction (continued)
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Introduction to Nanotechnology

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