Intensity of magnetization

Fig. 32. The integrated intensity of magnetic reflections of x-ray resonant exchange scattering measured for NdNi2BjC and SmNi2B2C. Dashed line and full line model calculations for a magnetic moment parallel to the tetragonal a-axis and c-axis, respectively (after Detlefs et al. 1997b).

The intensity of magnetization I induced at any point in u body is proportional to the strength of the applied field // ... [Pg.959]

Fig. 10 (a, b) Schematic mechanism demonstrated for a reflective color M-paper with magnetically controllable characteristics, (c, d) The intensity of magnetic field dependence on the reflection spectra of chiral nematic mixtures doped with magnetite nanoparticles that are surface modified with oleic acid and a chiral pyridine-based dopant, as well as photographs of both formulations before and after a magnetic field of 1,000 GS was applied (see photograph insets above) [364], (Copyright 2010, Taylor Francis)... [Pg.359]

One can explore what functions of each parameter matrix are actually obtainable by scientists using the above spin-Hamiltonian, via the measurable line positions and relative line intensities of magnetic-resonance spectra see publications by Skinner and Weil130 154 for some aspects of this. The question as to which parameter matrices occurring in Equation (A3) are directly available from experimental data is far from trivial7 26 matrices g, gn and A are not, while their squares (see below) are. [Pg.28]

Table 1. Relationship between X and the physical solute properties using different FFF techniques [27,109] with R=gas constant, p=solvent density, ps=solute density, co2r=centrifugal acceleration, V0=volume of the fractionation channel, Vc=cross-flow rate, E=electrical field strength, dT/dx=temperature gradient, M=molecular mass, dH=hydrodynamic diameter, DT=thermal diffusion coefficient, pe=electrophoretic mobility, %M=molar magnetic susceptibility, Hm=intensity of magnetic field, AHm=gradient of the intensity of the magnetic field, Ap = total increment of the chemical potential across the channel...

$Table 1. Relationship between X and the physical solute properties using different FFF techniques [27,109] with R=gas constant, p=solvent density, ps=solute density, co2r=centrifugal acceleration, V0=volume of the fractionation channel, Vc=cross-flow rate, E=electrical field strength, dT/dx=temperature gradient, M=molecular mass, dH=hydrodynamic diameter, DT=thermal diffusion coefficient, pe=electrophoretic mobility, %M=molar magnetic susceptibility, Hm=intensity of magnetic field, AHm=gradient of the intensity of the magnetic field, Ap = total increment of the chemical potential across the channel...$

Assume that the volume D is filled now with magnetic masses with the intensity of magnetization I(r). It is well known that the corresponding magnetic field H(r ) can be represented as follows (Zhdanov, 1988) ... [Pg.8]

I is called the intensity of magnetization. The ratio B/H, called the magnetic permeability of the material, is given by... [Pg.540]

Fig. 3.6 The effect of orientation upon the intensities of magnetic and quadrupole spectra for a f -> i transition.

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