Dynamic Light Scattering: Applications of Photon Correlation SpectroscopyR. Pecora In the twenty years since their inception, modern dynamic light-scattering techniques have become increasingly sophisticated, and their applications have grown exceedingly diverse. Applications of the techniques to problems in physics, chemistry, biology, medicine, and fluid mechanics have prolifer ated. It is probably no longer possible for one or two authors to write a monograph to cover in depth the advances in scattering techniques and the main areas in which they have made a major impact. This volume, which we expect to be the first of aseries, presents reviews of selected specialized areas by renowned experts. It makes no attempt to be comprehensive; it emphasizes a body of related applications to polymeric, biological, and colloidal systems, and to critical phenomena. The well-known monographs on dynamic light scattering by Berne and Pecora and by Chu were published almost ten years ago. They provided comprehensive treatments of the general principles of dynamic light scat tering and gave introductions to a wide variety of applications, but natu rally they could not treat the new applications and advances in older ones that have arisen in the last decade. The new applications include studies of interacting particles in solution (Chapter 4); scaling approaches to the dynamics of polymers, including polymers in semidilute solution (Chapter 5); the use of both Fabry-Perot interferometry and photon correlation spectroscopy to study bulk polymers (Chapter 6); studies of micelIes and microemulsions (Chapter 8); studies of polymer gels (Chapter 9). |
Contents
I | 1 |
II | 6 |
III | 7 |
V | 8 |
VI | 11 |
VII | 12 |
VIII | 15 |
IX | 16 |
LXXVII | 221 |
LXXVIII | 240 |
LXXIX | 241 |
LXXX | 245 |
LXXXIII | 246 |
LXXXIV | 247 |
LXXXV | 256 |
LXXXVI | 262 |
X | 19 |
XII | 20 |
XIII | 26 |
XIV | 29 |
XV | 35 |
XVI | 40 |
XVII | 42 |
XVIII | 43 |
XIX | 46 |
XX | 48 |
XXI | 49 |
XXII | 50 |
XXIII | 51 |
XXV | 53 |
XXVI | 56 |
XXVIII | 57 |
XXX | 59 |
XXXII | 60 |
XXXIII | 61 |
XXXIV | 65 |
XXXV | 68 |
XXXVI | 69 |
XXXVII | 72 |
XXXVIII | 75 |
XXXIX | 79 |
XL | 80 |
XLI | 81 |
XLII | 85 |
XLIV | 90 |
XLV | 91 |
XLVI | 92 |
XLVII | 94 |
XLVIII | 96 |
XLIX | 97 |
L | 101 |
LI | 103 |
LII | 108 |
LIII | 114 |
LIV | 120 |
LV | 126 |
LVI | 130 |
LVII | 136 |
LVIII | 137 |
LIX | 142 |
LX | 144 |
LXI | 145 |
LXII | 149 |
LXIII | 154 |
LXIV | 158 |
LXV | 159 |
LXVI | 162 |
LXVII | 164 |
LXVIII | 171 |
LXIX | 181 |
LXXI | 182 |
LXXII | 186 |
LXXIII | 193 |
LXXIV | 200 |
LXXV | 214 |
LXXVI | 217 |
LXXXVII | 267 |
LXXXVIII | 272 |
LXXXIX | 273 |
XC | 277 |
XCII | 280 |
XCIV | 288 |
XCV | 291 |
XCVI | 292 |
XCVII | 293 |
XCVIII | 294 |
XCIX | 295 |
C | 297 |
CI | 299 |
CII | 300 |
CIV | 301 |
CV | 305 |
CVI | 308 |
CVII | 313 |
CIX | 328 |
CX | 337 |
CXI | 340 |
CXII | 341 |
CXIII | 347 |
CXV | 348 |
CXVI | 350 |
CXVII | 351 |
CXVIII | 352 |
CXIX | 354 |
CXX | 356 |
CXXI | 357 |
CXXIII | 361 |
CXXV | 363 |
CXXVI | 364 |
CXXVIII | 365 |
CXXIX | 366 |
CXXX | 367 |
CXXXII | 368 |
CXXXIII | 369 |
CXXXIV | 370 |
CXXXV | 371 |
CXXXVI | 373 |
CXXXVII | 374 |
CXXXVIII | 376 |
CXL | 381 |
CXLI | 388 |
CXLII | 390 |
CXLIII | 392 |
CXLIV | 394 |
CXLV | 396 |
CXLVIII | 397 |
CXLIX | 398 |
CL | 399 |
CLI | 401 |
CLII | 402 |
CLIII | 404 |
CLIV | 405 |
CLV | 406 |
417 | |
Other editions - View all
Dynamic Light Scattering: Applications of Photon Correlation Spectroscopy R. Pecora Limited preview - 2013 |
Dynamic Light Scattering: Applications of Photon Correlation Spectroscopy R. Pecora No preview available - 2011 |
Dynamic Light Scattering: Applications of Photon Correlation Spectroscopy R. Pecora No preview available - 2011 |
Common terms and phrases
aggregation analysis autocorrelation function B. R. Ware behavior bile salt Biophys Biopolymers blob Brillouin Brownian particles calculated chain Chem collective diffusion Colloid concentration dependence correlation function critical decay density depolarized diffusion coefficient dilute dynamic light scattering dynamic structure factor effects equation experimental exponential exponential decay exponents Figure fluctuations fluid frequency G. B. Benedek hydrodynamic interactions hydrodynamic radius interparticle ionic laser length Lett limit linewidth liquid Macromolecules measured micellar micelles microemulsions mode molecular weight molecules monomer motion NaCl observed obtained Oseen tensor P. N. Pusey parameters Pecora phase photomultiplier photon correlation spectroscopy Phys polarized polydispersity polymer polystyrene predicted protein radius ratio Rayleigh regime relaxation rotational diffusion sample scaling scattered intensity scattered light scattering experiments Section self-diffusion semidilute shear solution solvent spectrum spherical suspension techniques temperature theoretical theory tion transition values vector velocity viscosity volume fraction
Popular passages
Page 345 - Water structure and changes in thermal stability of the system poly(ethylene oxide)-water.