7 research outputs found
Simulation of Reciprocal Space Maps for Thin Ion-Implanted Layers in Yttrium-Iron Garnet Films with Defects
Numerical simulation of the reciprocal space maps measured from the ion-implanted single-crystal yttrium-iron garnet films on gadolinium-gallium garnet substrate has been carried out basing on the theoretical model of the triple-crystal dynamical diffractometry of crystalline multilayer systems with inhomogeneous strain distributions and randomly distributed defects. The presence of growth defects in both film and substrate as well as radiation defects created in subsurface layer of nanometer-scale thickness after 90
keV F+ ion implantation was taken into account in the proposed model of the film system
Dynamical X-Ray Diffraction Characterization of the Self-Organized Quantum Dot Formation In Imperfect Semiconductor Superlattices
The self-organized quantum dot (QD) formation in InGaAs/GaAs superlattices grown by molecular beam epitaxy was investigated by the high-resolution X-ray diffraction technique. The investigated samples had the identical structure consisting of fifteen periods of {InxGa1−xAs (8 ML)/GaAs (26 ML)} with the nominal In concentration x = 0.2. The diffraction profiles and reciprocal lattice maps for these samples have been measured at symmetrical (004) reflection by using the triple-crystal X-ray diffractometer. The analysis of the measured data was performed by using the proposed diffraction model based on the statistical theory of dynamical X-ray scattering in imperfect single crystals and multilayer structures
Simulation of Reciprocal Space Maps for Thin Ion-Implanted Layers in Yttrium-Iron Garnet Films with Defects
Numerical simulation of the reciprocal space maps measured from the ion-implanted single-crystal yttrium-iron garnet films on gadolinium-gallium garnet substrate has been carried out basing on the theoretical model of the triple-crystal dynamical diffractometry of crystalline multilayer systems with inhomogeneous strain distributions and randomly distributed defects. The presence of growth defects in both film and substrate as well as radiation defects created in subsurface layer of nanometer-scale thickness after 90
keV F+ ion implantation was taken into account in the proposed model of the film system
Transformations of microdefect structure in silicon crystals under the influence of weak magnetic field
Quantitative characterization of complex microdefect structures in annealed
silicon crystals (1150 °С, 40 h) and their transformations after exposing for one day in a
weak magnetic field (1 T) has been performed by analyzing the rocking curves, which
have been measured by a high-resolution double-crystal X-ray diffractometer. Based on
the characterization results, which have been obtained by using the formulas of the
dynamical theory of X-ray diffraction by imperfect crystals with randomly distributed
microdefects of several types, the concentrations and average sizes of oxygen precipitates
and dislocation loops after imposing the magnetic field and their dependences on time
after its removing have been determined
X-Ray Diffraction Characterization of Nanoscale Strains and Defects in Yttrium Iron Garnet Films Implanted with Fluorine Ions
The theoretical diffraction model for a crystalline multilayer system with inhomogeneous strain profile and randomly distributed defects has been created by using the statistical dynamical theory of X-ray diffraction in imperfect crystals. The dynamical scattering peculiarities in both coherent and diffuse scattering intensities have been taken into account for all the layers of the system by using derived recurrence relations between coherent scattering amplitudes.
The investigated yttrium-iron garnet films grown on gadolinium-gallium garnet substrate were implanted with different doses of 90 keV F+ ions. The rocking curves measured from the as-grown and implanted samples have been treated by using the proposed theoretical model. This model has allowed for the reliable self-consistent determination of strain profile parameters and structural defect characteristics in both implanted film and substrate of the investigated samples
Double- and triple-crystal X-ray diffractometry of microdefects in silicon
The generalized dynamical theory of X-ray scattering by real single crystals
allows to self-consistently describe intensities of coherent and diffuse scattering
measured by double- and triple-crystal diffractometers (DCD and TCD) from single
crystals with defects in crystal bulk and with strained subsurface layers. Being based on
this theory, we offer the combined DCD+TCD method that exhibits the higher sensitivity
to defect structures with wide size distributions as compared with any of these methods
alone. In the investigated Czochralski-grown silicon crystals, the sizes and concentrations
of small oxygen precipitates as well as small and large dislocation loops have been
determined using this method
Comprehensive investigation of defects in highly perfect silicon single crystals
We used X-ray diffraction method of total rocking curves and nondestructive direct observation techniques (atomic force and scanning electron microscopies) to quantitatively determine the defect characteristics (radii and concentrations) for the main types of defects in Czochralski-grown silicon single crystals annealed at 750 °С