Contemporary Diffraction Methods in Study of Polycrystals

Abstract: Diffraction in the polycrystal/crystalline powder is one of the most powerful techniques in study of microstructure and crystal structure of solids. This technique enables, in synergy with microscopic, spectroscopic and other physical techniques, a complete analysis of onephase and multi-phase substances, that are important in scientific and technological fields. Information on microstructure and crystal structure of a substance is stored in its diffraction pattern; in order to reveal this information, the dif… Show more

“…The doping methods have been applied in a series of author's studies, among others, in the study of the phase transition in titanium dioxide [18,19], biomineralization processes in the oyster Ostrea edulis [20,21], crystalline phases in intermetallic oxides [22][23][24][25][26][27], precipitation processes in Al-Zn alloys [11][12][13]19].…”

“…Therefore, one can find the molar fractions of the phases R and A by comparison of the measured intensities and the intensities of diffraction lines calculated on the basis of the crystal structure of R and A, for instance, of the R diffraction line 110, and of the A diffraction line 101, according to R ⁄ A = 1.25 I110R ⁄I101A. At several temperatures, the molar ratio was also checked at RT by the doping method, after quenching the sample to RT [18,19]. [19].…”

“…At several temperatures, the molar ratio was also checked at RT by the doping method, after quenching the sample to RT [18,19]. [19].…”

“…An extensive study of Al-Zn alloys, with the molar zinc content, x(Zn), up to 0.62 by XRD, TEM, and DTA resulted in many new information on the microstructure of the alloys (unit-cell parameters, crystallite size and shape, strains, phase fractions, thermal expansion, etc. ), in dependence on the initial composition, applied thermal treatment, and temperature [12,13,19]. Essential points from References [12,19] are given here.…”

“…), in dependence on the initial composition, applied thermal treatment, and temperature [12,13,19]. Essential points from References [12,19] are given here. The alloys rapidly quenched from a temperature, T t , higher than the solid-solution temperature, T ss , to RT are supersaturated solid solutions.…”

Quantitative Phase Analysis by X-ray Diffraction—Doping Methods and Applications

“…The doping methods have been applied in a series of author's studies, among others, in the study of the phase transition in titanium dioxide [18,19], biomineralization processes in the oyster Ostrea edulis [20,21], crystalline phases in intermetallic oxides [22][23][24][25][26][27], precipitation processes in Al-Zn alloys [11][12][13]19].…”

“…Therefore, one can find the molar fractions of the phases R and A by comparison of the measured intensities and the intensities of diffraction lines calculated on the basis of the crystal structure of R and A, for instance, of the R diffraction line 110, and of the A diffraction line 101, according to R ⁄ A = 1.25 I110R ⁄I101A. At several temperatures, the molar ratio was also checked at RT by the doping method, after quenching the sample to RT [18,19]. [19].…”

“…At several temperatures, the molar ratio was also checked at RT by the doping method, after quenching the sample to RT [18,19]. [19].…”

“…An extensive study of Al-Zn alloys, with the molar zinc content, x(Zn), up to 0.62 by XRD, TEM, and DTA resulted in many new information on the microstructure of the alloys (unit-cell parameters, crystallite size and shape, strains, phase fractions, thermal expansion, etc. ), in dependence on the initial composition, applied thermal treatment, and temperature [12,13,19]. Essential points from References [12,19] are given here.…”

“…), in dependence on the initial composition, applied thermal treatment, and temperature [12,13,19]. Essential points from References [12,19] are given here. The alloys rapidly quenched from a temperature, T t , higher than the solid-solution temperature, T ss , to RT are supersaturated solid solutions.…”

Quantitative Phase Analysis by X-ray Diffraction—Doping Methods and Applications