Laser Light Scattering: Basic Principles and PracticeEmphasizes the basic principles and applications of light scattering, and covers developments in the use of fibre optics for light scattering instrumentation, and the method of maximum entropy for Laplace inversion of time correlations functions. The book is based on a course taught by the author. |
Contents
LIGHT SCATTERING THEORY | 13 |
OPTICAL MIXING SPECTROSCOPY | 63 |
PHOTON CORRELATION SPECTROSCOPY | 93 |
Copyright | |
7 other sections not shown
Common terms and phrases
angular angular aperture aperture autocorrelation function average Benedek channels clipping coherence component computed correlation function count rate d₁ delay delay-time increment density detection optics detector Dhadwal diameter dielectric dynamic light scattering electric field electric susceptibility entropy Equation etalon experimental Fabry-Perot factor fiber-optic filter fluctuations frequency Gaussian heterodyne incident beam intensity-intensity inversion ion laser k₁ L₂ laser beam laser light scattering Lastovka lens macromolecules maximum-entropy measurements microlens molecular weight noise normalized nsec optical fiber optical mixing spectroscopy parameters particle photocathode photocount photocurrent photoelectron photoelectron pulses photomultiplier Phys Pike pinhole polarization polymer polymer solution problem PTFE range Rayleigh ratio reader refractive index sampling time interval scattered electric field scattered light scattering angle scattering cell scattering medium scattering volume schematic Section shown in Fig signal single-clipped solid angle solvent spatial spectral spectrum statistical technique temperature tube vector wave wavelength