- Page 2 and 3:
INTRODUCTION TO NANOTECHNOLOGY Char
- Page 4 and 5:
CONTENTS Preface xi 1 Introduction
- Page 6 and 7:
5.2 Carbon Molecules 103 5.2.1 Natu
- Page 8 and 9:
9.4 Excitons 244 9.5 Single-Electro
- Page 10 and 11:
PREFACE In recent years nanotechnol
- Page 12 and 13:
INTRODUCTION The prefix nano in the
- Page 14 and 15:
INTRODUCTION 3 he recognized the ex
- Page 16 and 17:
1000 (I) a 900 4 800 a 900 I 6 700
- Page 18 and 19:
INTRODUCTION 7 developed before the
- Page 20 and 21:
2.1. STRUCTURE 9 mechanics, the res
- Page 22 and 23:
X T 2.1. STRUCTURE 11 Figure 2.4. C
- Page 24 and 25:
2.1. STRUCTURE 13 Figure 2.6. Thirt
- Page 26 and 27:
Sodium Nanoparticle Na, Magic Numbe
- Page 28 and 29:
2.1. STRUCTURE 17 of the large anio
- Page 30 and 31:
2.1. STRUCTURE 19 other, and high-f
- Page 32 and 33:
2.2. ENERGY BANDS 21 Conduction Ban
- Page 34 and 35:
2.2. ENERGY BANDS 23 Figure 2.13. S
- Page 36 and 37:
2.2. ENERGYBANDS 25 band at point T
- Page 38 and 39:
A X ' Wavevector A Si c z 2.2. ENER
- Page 40 and 41:
2.2. ENERGY BANDS 29 bands of Figs.
- Page 42 and 43:
2.3. LOCALIZED PARTICLES 31 add ele
- Page 44 and 45:
1 meV 10 meV 100 meV FJ E W 1 eV 10
- Page 46 and 47:
3 METHODS OF MEASURING PROPERTIES 3
- Page 48 and 49:
3.2. STRUCTURE 37 Table 3.1. Crysta
- Page 50 and 51:
3.2. STRUCTURE 39 Figure 3.2. Two-d
- Page 52 and 53:
3.2. STRUCTURE 41 The widths of the
- Page 55 and 56:
44 METHODS OF MEASURING PROPERTIES
- Page 57 and 58:
46 METHODS OF MEASURING PROPERTIES
- Page 59 and 60:
48 METHODS OF MEASURING PROPERTIES
- Page 62 and 63:
3.3. MICROSCOPY 51 types of transit
- Page 64 and 65:
3.3. MICROSCOPY 53 Actual diverging
- Page 66 and 67:
Tunneling current Tunneling current
- Page 68 and 69:
3.3. MrCAOSCOPY 57 and the latter m
- Page 70 and 71:
3.4. SPECTROSCOPY 59 From Eq. (3.8)
- Page 72 and 73:
1 Average Panicle FWHM Size (nm) in
- Page 74 and 75:
CdSe colloidal NCs a = 1.2 nrn 3.4.
- Page 76 and 77:
El X-RAY TUBE 8000 - A 6000 - 4000
- Page 78 and 79:
2 N I w 3.0 2.5 2.0 1.5 1 .o 0.5 3.
- Page 80 and 81:
i 3.4. SPECTROSCOPY 69 NMR involves
- Page 82 and 83:
T=220K - 2G H FURTHER READING 71 Fi
- Page 84 and 85:
NUMBER OF ATOMS RADIUS (nm) 1 10 1
- Page 86 and 87:
I L 7 3 5 7 9 11 13 15 17 NUMBER OF
- Page 88 and 89:
JELLIUM MODEL OF CLUSTERS ATOMS CLU
- Page 90 and 91:
1.02 { 1.01 - 1 - 0.99 - 4.2. METAL
- Page 92 and 93:
4.2. METAL NANOCLUSTERS 81 Figure 4
- Page 94 and 95:
4.2. METAL NANOCLUSTERS 83 Figure 4
- Page 96 and 97:
-0 100 200 300 400 500 600 MASSICHA
- Page 98 and 99:
a 42. METAL NANOCLUSTERS 87 Figure
- Page 100 and 101:
. . . .. . - . D 111111111111111111
- Page 102 and 103:
3 4 2.5 0 cn g 2 0 z d 1.5 t a 9 1
- Page 104 and 105:
4.3. SEMICONDUCTING NANOPARTICLES 9
- Page 106 and 107:
4.4. RARE GAS AND MOLECULAR CLUSTER
- Page 108 and 109:
4.5. METHODS OF SYNTHESIS 97 d Figu
- Page 110 and 111:
4.5. METHODS OF SYNTHESIS 99 isopro
- Page 112 and 113:
PULSED LASER BEAM 1 1 1 1 1 I ROTAT
- Page 114 and 115:
5.1. INTRODUCTION CARBON NANOSTRUCT
- Page 116 and 117: 5.2. CARBON MOLECULES 105 methane d
- Page 118 and 119: 5.3. CARBON CLUSTERS 107 -0 20 40 6
- Page 120 and 121: PHOTON ENERGY (electron volts) 5.3.
- Page 122 and 123: Figure 5.6. Structure of the CEO fu
- Page 124 and 125: 1 30 0 14.1 14.2 14.3 14.4 14.5 LAT
- Page 126 and 127: (c) 5.4. CARBON NANOTUBES 115 Figur
- Page 128 and 129: 5.4. CARBON NANOTUBES 1 17 The mech
- Page 130 and 131: 5.4. CARBON NANOTUBES 11 9 investig
- Page 132 and 133: 5.4. CARBON NANOTUBES 121 energy gr
- Page 134 and 135: 5.4. CARBON NANOTUBES 123 stretch c
- Page 136 and 137: 5.5. APPLICATIONS OF CARBON NANOTUB
- Page 138 and 139: 5.5. APPLICATIONS OF CARBON NANOTUB
- Page 140 and 141: - v) 450 : 400 3 350 1 300 : 5 250
- Page 142 and 143: 5.5. APPLICATIONS OF CARBON NANOTUB
- Page 144 and 145: BULK NANOSTRUCTURED MATERIALS In th
- Page 146 and 147: h 8 0 6.1. SOLID DISORDERED NANOSTR
- Page 148 and 149: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 150 and 151: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 152 and 153: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 154 and 155: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 156 and 157: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 158 and 159: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 160 and 161: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 162 and 163: 6.1. SOLID DISORDERED NANOSTRUCTURE
- Page 164 and 165: 6.2. NANOSTRUCTURED CRYSTALS 153 qu
- Page 168 and 169: 6.2.4. Crystals of Metal Nanopartic
- Page 170 and 171: 6.2. NANOSTRUCTURED CRYSTALS 159 re
- Page 172 and 173: 6.2. NANOSTRUCTURED CRYSTALS 161 Fi
- Page 174 and 175: 6.2. NANOSTRUCTURED CRYSTALS 163 se
- Page 176 and 177: 7.1. BASICS OF FERROMAGNETISM 7 NAN
- Page 178 and 179: 7.1. BASICS OF FERROMAGNETISM 167 a
- Page 180 and 181: INITIAL CONFIGURATION ,i:k DOMAIN R
- Page 182 and 183: 7.2. EFFECT OF BULK NANOSTRUCTURING
- Page 184 and 185: - - m Lo v a? 7.3. DYNAMICS OF NANO
- Page 186 and 187: 7.3. DYNAMICS OF NANOMAGNETS 175 Fi
- Page 188: 16 w U 3 10 2 U w i 6 , , , , ,,, ,
- Page 191 and 192: 180 NANOSTRUCTURED FERROMAGNETISM 0
- Page 193 and 194: 182 NANOSTRUCTURED FERROMAGNETISM N
- Page 195 and 196: 184 NANOSTRUCTURED FERROMAGNETISM 2
- Page 197 and 198: 186 NANOSTRUCTURED FERROMAGNETISM 1
- Page 199 and 200: iaa NANOSTRUCTURED FERROMAGNETISM t
- Page 201 and 202: P w9
- Page 203 and 204: 192 NANOSTRUCTURED FERROMAGNETISM d
- Page 205 and 206: 8 OPTICAL AND VIBRATIONAL SPECTROSC
- Page 207 and 208: 196 OPTICAL AND VIBRATIONAL SPECTRO
- Page 209 and 210: 198 OPTICAL AND VIBRATIONAL SPECTRO
- Page 211 and 212: 200 OPTICAL AND VIBRATIONAL SPECTRO
- Page 213 and 214: 202 OPTICAL AND VIBRATIONAL SPECTRO
- Page 215 and 216: 204 OPTICAL AND VIBRATIONAL SPECTRO
- Page 217 and 218:
206 OPTICAL AND VIBRATIONAL SPECTRO
- Page 219 and 220:
208 OPTICAL AND VIBRATIONAL SPECTRO
- Page 221 and 222:
210 OPTICAL AND VIBRATIONAL SPECTRO
- Page 223 and 224:
212 OPTICAL AND VIBRATIONAL SPECTRO
- Page 225 and 226:
214 OPTICAL AND VIBRATIONAL SPECTRO
- Page 227 and 228:
216 OPTICAL AND VIBRATIONAL SPECTRO
- Page 229 and 230:
218 OPTICAL AND VIBRATIONAL SPECTRO
- Page 231 and 232:
220 OPTICAL AND VIBRATIONAL SPECTRO
- Page 233 and 234:
222 OPTICAL AND VIBRATIONAL SPECTRO
- Page 235 and 236:
224 OPTICAL AND VIBRATIONAL SPECTRO
- Page 237 and 238:
QUANTUM WELLS, WIRES, AND DOTS 9.1.
- Page 239 and 240:
f37 228 QUANTUM WELLS, WIRES, AND D
- Page 241 and 242:
230 QUANTUM WELLS. WIRES, AND DOTS
- Page 243 and 244:
232 QUANTUM WELLS, WIRES, AND DOTS
- Page 245 and 246:
234 QUANTUM WELLS, WIRES, AND DOTS
- Page 247 and 248:
236 QUANTUM WELLS, WIRES, AND DOTS
- Page 249 and 250:
238 QUANTUM WELLS, WIRES, AND DOTS
- Page 251 and 252:
240 QUANTUM WELLS, WIRES, AND DOTS
- Page 253 and 254:
242 QUANTUM WELLS, WIRES, AND DOTS
- Page 255 and 256:
244 QUANTUM WELLS, WIRES, AND DOTS
- Page 257 and 258:
246 QUANTUM WELLS, WIRES, AND DOTS
- Page 259 and 260:
248 QUANTUM WELLS, WIRES, AND DOTS
- Page 261 and 262:
250 QUANTUM WELLS, WIRES, AND DOTS
- Page 263 and 264:
252 QUANTUM WELLS, WIRES, AND DOTS
- Page 265 and 266:
254 QUANTUM WELLS, WIRES, AND DOTS
- Page 267 and 268:
256 QUANTUM WELLS, WIRES, AND DOTS
- Page 269 and 270:
258 SELF-ASSEMBLY AND CATALYSIS err
- Page 271 and 272:
260 SELF-ASSEMBLY AND CATALYSIS the
- Page 273 and 274:
262 SELF-ASSEMBLY AND CATALYSIS Fig
- Page 275 and 276:
264 SELF-ASSEMBLY AND CATALYSIS pas
- Page 277 and 278:
266 SELF-ASSEMBLY AND CATALYSIS 351
- Page 279 and 280:
268 SELF-ASSEMBLY AND CATALYSIS sam
- Page 281 and 282:
270 SELF-ASSEMBLY AND CATALYSIS I I
- Page 283 and 284:
272 SELF-ASSEMBLY AND CATALYSIS 20
- Page 285 and 286:
274 SELF-ASSEMBLY AND CATALYSIS Fig
- Page 287 and 288:
276 SELF-ASSEMBLY AND CATALYSIS Fig
- Page 289 and 290:
278 SELF-ASSEMBLY AND CATALYSIS /O\
- Page 291 and 292:
280 SELF-ASSEMBLY AND CATALYSIS so,
- Page 293 and 294:
282 ORGANIC COMPOUNDS AND POLYMERS
- Page 295 and 296:
284 ORGANIC COMPOUNDS AND POLYMERS
- Page 297 and 298:
286 ORGANIC COMPOUNDS AND POLYMERS
- Page 299 and 300:
288 ORGANIC COMPOUNDS AND POLYMERS
- Page 301 and 302:
290 ORGANIC COMPOUNDS AND POLYMERS
- Page 303 and 304:
292 ORGANIC COMPOUNDS AND POLYMERS
- Page 305 and 306:
294 ORGANIC COMPOUNDS AND POLYMERS
- Page 307 and 308:
296 ORGANIC COMPOUNDS AND POLYMERS
- Page 309 and 310:
298 ORGANIC COMPOUNDS AND POLYMERS
- Page 311 and 312:
300 ORGANIC COMPOUNDS AND POLYMERS
- Page 313 and 314:
302 ORGANIC COMPOUNDS AND POLYMERS
- Page 315 and 316:
304 ORGANIC COMPOUNDS AND POLYMERS
- Page 317 and 318:
306 ORGANIC COMPOUNDS AND POLYMERS
- Page 319 and 320:
308 ORGANIC COMPOUNDS AND POLYMERS
- Page 321 and 322:
12 BIOLOGICAL MATERIALS 12.1. INTRO
- Page 323:
31 2 BIOLOGICAL MATERIALS Another c
- Page 326 and 327:
12.2. BIOLOGICAL BUILDING BLOCKS 31
- Page 328 and 329:
NAME Glycine Alanine Valine Threoni
- Page 330 and 331:
Attachment point for next desoxyrib
- Page 332 and 333:
12.3. NUCLEIC ACIDS 321 Figure 12.1
- Page 334 and 335:
12.3. NUCLEIC ACIDS 323 alphabet th
- Page 336 and 337:
12.4. BIOLOGICAL NANOSTRUCTURES 325
- Page 338 and 339:
water water water 0 Air oil 12.4. B
- Page 340 and 341:
12.4. BIOLOGICAL NANOSTRUCTURES 329
- Page 342 and 343:
1 L+~-&Iq#J FURTHER READING 331 + +
- Page 344 and 345:
13.1. MICROELECTROMECHANICAL SYSTEM
- Page 346 and 347:
13.2. NANOELECTROMECHANICAL SYSTEMS
- Page 348 and 349:
13.2. NANOELECTROMECHANICAL SYSTEMS
- Page 350 and 351:
13.2. NANOELECTROMEGHANICAL SYSTEMS
- Page 352 and 353:
13.2. NANOELECTROMECHANICAL SYSTEMS
- Page 354 and 355:
13.2. NANOELECTROMECHAsrlICAL SYSTE
- Page 356 and 357:
CANTILEVER \ \ \ \ 13.3. MOLECULAR
- Page 358 and 359:
13.3. MOLECULAR AND SUPRAMOLECULAR
- Page 360 and 361:
13.3. MOLECULAR AND SUPRAMOLECULAR
- Page 362 and 363:
Gold electrode 13.3. MOLECULAR AND
- Page 364 and 365:
13.3. MOLECULAR AND SUPRAMOLECULAR
- Page 366:
FURTHER READING 355 D. Ruger and F!
- Page 369 and 370:
358 FORMULAS FOR DIMENSIONALITY Tab
- Page 371 and 372:
0 Q) 0 Table A.3. Number of electro
- Page 373 and 374:
362 TABULATIONS OF SEMICONDUCTING M
- Page 375 and 376:
364 TABULATIONS OF SEMICONDUCTING M
- Page 377 and 378:
366 TABULATIONS OF SEMICONDUCTING M
- Page 379 and 380:
368 TABULATIONS OF SEMICONDUCTING M
- Page 382 and 383:
abalone mollusk, 1 absorption coeff
- Page 384 and 385:
one, 324 bongo drum, 2 Bose-Einstei
- Page 386 and 387:
explosion, 93 force, 244 interactio
- Page 388 and 389:
sublattice, 15 unit cell figure, 12
- Page 390 and 391:
hydroxyproline, 324, 325 hyperfoldi
- Page 392 and 393:
effective, see effective mass mean
- Page 394 and 395:
nuclear fusion, 94 deuterium cluste
- Page 396 and 397:
Re (rhenium) nanoparticle magnetic
- Page 398 and 399:
thermal conductivity of semiconduct