74 at.% W, whereas the composition of the thinner areas was 34 ± 1.2 at.% W. Figure 10 shows the EDS spectra graphs of K and L lines for points 1 and 3. The presence of Cu, corresponding to the signal from the copper TEM grid supporting the specimen, and oxygen was clearly seen. Figure 9 STEM image of the NiW alloy structure with the points of EDS analysis. Table 1 Ni and W content of NiW alloy at the points of interest using EDS analysis Atomic
percentage of Ni C188-9 clinical trial Atomic Belinostat percentage of W Spectrum 1 70.55 29.45 Spectrum 2 66.73 33.27 Spectrum 3 65.03 34.97 Spectrum 4 70.46 29.54 Spectrum 5 69.23 30.77 CoW alloy had a similar composition distribution. Figure 11 shows the STEM image of the CoW alloy structure with points for EDS analysis. Table 2 shows the results of the processed EDS spectra. Figure 12 shows the EDS spectra graphs of K and L lines for points 1 and 3. The average composition of the thicker areas was 34 ± 2.6 at.% W, whereas the thinner areas Semaxanib supplier were 52 ± 1.5 at.% W. Electron spectroscopic images (ESI) obtained by EELS for the nickel and cobalt K lines showed the heterogeneous distribution in the alloy structure. Figures 13 and 14 show the images for nickel and cobalt, respectively. The presence of structural and compositional inhomogeneities in the alloys was clearly seen. Figure 10 The EDS spectra of K and L lines of NiW in points 1 and 3 (Figure 9 ). Figure 11 STEM image of the CoW alloy structure with the point
for EDS analysis. Table 2 Co and W content of the CoW alloy at the points of interest using EDS analysis Atomic percentage of Co Atomic percentage of W Spectrum 1 68.25 31.75 Spectrum 2 47.80 52.20 Spectrum 3 46.40
53.60 Spectrum 4 49.33 Prostatic acid phosphatase 50.67 Spectrum 5 64.64 35.36 Figure 12 The EDS spectra of K and L lines of CoW in points 1 and 3 (Figure 11 ). Figure 13 ESI image of the nickel map, taken from the Libra at 200 kV. Figure 14 ESI image of the cobalt map, taken from the Libra at 200 kV. Conclusions Investigations showed the presence of structural and compositional inhomogeneities in the CoW-CoNiW-NiW alloys. Atomic electron microscopy allowed us to determine the preferential areas of the structural relaxation and crystallization processes. The most intensive nanocrystal growth occurs on free surfaces. Based on direct observation of the atoms’ movements, it was determined that the diffusion coefficient is in the range of 0.9 to 1.7 × 10–18 m2/s, which was significantly higher than the volume diffusion coefficient for similar alloys. This can be explained by the prevalence of surface diffusion, which can exceed volume diffusion by three to five orders of magnitude [26–28]. It was found that local changes in the composition can reach 18 at.% for the CoW alloy and 4 at.% for the NiW alloy. In addition, tungsten is more homogeneously distributed than nickel or cobalt. This is associated with the higher mobility of nickel and cobalt atoms in the electrolyte.