Neutrons, X-rays and Light: Scattering Methods Applied to Soft Condensed MatterP. Lindner, Th. Zemb Scattering experiments, using X-ray, light and neutron sources (in historical order) are key techniques for studying structure and dynamics in systems containing colliods, polymers, surfactants and biological macromolecules, summarized here as soft condensed matter. The education in this field in Europe is very heterogeneous and frequently inadequate, which severely limits an efficient use of these methods, especially at large-scale facilities. The series of "Bombannes" schools and the completely revised and updated second edition of the lecture notes are devoted to a practical approach to current methodology of static and dynamic techiques. Basic information on data interpretation, on the complementarity of the different types of radiation, as well as information on recent applications and developments is presented. The aim is to avoid over - as well as under-exploitation of data. |
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... random walk - The random walk is the simplest possible model that provides us with the description of the conformation of a polymer chain in solution . In the random walk model , we interpret the line that we generate by performing a random ...
... random walk - The random walk is the simplest possible model that provides us with the description of the conformation of a polymer chain in solution . In the random walk model , we interpret the line that we generate by performing a random ...
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... random walk ( RW ) to a so - called self avoiding walk ( SAW ) . In its simplest version we can use the following model : • Consider all random walks with N - 1 steps . • Reject all random walks with multiple occupancy of a lattice site ...
... random walk ( RW ) to a so - called self avoiding walk ( SAW ) . In its simplest version we can use the following model : • Consider all random walks with N - 1 steps . • Reject all random walks with multiple occupancy of a lattice site ...
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... random walk behavior can be taken as a simple example , and it is schematically drawn in Fig . 18A : For a random walk with local stiffness we expect to walk first along a certain direction on a lattice . After a characteristic number ...
... random walk behavior can be taken as a simple example , and it is schematically drawn in Fig . 18A : For a random walk with local stiffness we expect to walk first along a certain direction on a lattice . After a characteristic number ...
Contents
P N Pusey | 4 |
Shapes and Interactions | 12 |
Experimental Aspects Initial Data Reduction | 23 |
Copyright | |
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Common terms and phrases
amplitude Appl approximation average beam calculated cell Chem coefficients collimation colloidal concentration constant contrast variation correlation function corresponding Cryst crystals curvature cylinder dependence detector deuterated differential scattering cross-section dilute distance droplets dynamic light scattering effects fluctuations form factor Fourier transform Gaussian Glatter Guinier homogeneous incoherent scattering instrument interactions lamellar Lindner Macromolecules measured method micelles microemulsion microstructure molar mass molecular molecules monomers multiple scattering neutron scattering obtained optical parameter particles PDDF peak Pedersen phase photons Phys plot polydisperse polymer Porod radiation radius of gyration random walk range refractive index regime sample SAXS scattered intensity scattering angle scattering curve scattering experiments scattering function scattering length scattering length density scattering vector Schurtenberger shear shown in Fig simulations small-angle scattering solution solvent spheres spherical static light scattering structure factor surface surfactant suspension technique temperature thickness volume fraction wavelength X-ray Zemb ΦΩ