During EBSD scanning, the samples were tilted, so the electron beam penetrated under the Cu NPs or into the pores of PS, detecting internal Si crystals in the pore walls. That introduced an error in the phase distribution.

Nevertheless, GW572016 it is shown that films deposited by Cu immersion deposition on Si and PS are noncontinuous, have a crystalline nature, and consist of Cu and Cu2O crystals of the cubic lattice cell. CuO was not found. The step size of EBSD scanning was 10 nm, which means that crystals of such dimensions exist in the deposited films. It should be noticed that Cu NPs deposited on the bulk Si (100) are check details oxidized more (amount of Cu2O is 13%) than other samples (Table 1). Figure 3 EBSD phase maps. Illustrations of phase discrimination were obtained for the surface region of samples (a) Cu/Si (100), (b) Cu/PS/Si (100), (c) Cu/Si (111), and (d) Cu/PS/Si (111). Table 1 Results of EBSD analysis of bulk Si and PS surfaces covered with www.selleckchem.com/products/eft-508.html Cu Sample type Phase Percentage (%) Count Area (mm2) Orientation Lattice cell Cu/Si (100) Not detected 15.9 437 0.03 None Unsolved points Silicon 42.9 1,182 0.07 (100) Face-centered cubic system Copper 28.2 778 0.05 (100) Face-centered cubic

system Cu2O 13.0 357 0.02 (100) Primitive cubic system Cu/PS/Si (100) Not detected 41.9 1,436 0.08 None Unsolved points Silicon 37.3 1,278 0.07 (100) Face-centered cubic system Copper 20.3 695 0.04 (100) Face-centered cubic system Cu2O 0.5 16 0.00 (100) Primitive cubic system Cu/Si (111) Not detected 0.00 0 0.00 None Unsolved points Silicon 64.3 2,140 0.12 (111) Face-centered cubic system Copper 32.0 1,065 0.06 (111) Face-centered cubic system Cu2O 3.8 125 0.01 (111) Primitive cubic system Cu/PS/Si (111) Not detected 26.0 863 0.05 None Unsolved points Silicon 49.5 1,642 0.10 Adenylyl cyclase (111) Face-centered cubic system Copper 23.2 770 0.04 (111)

Face-centered cubic system Cu2O 1.3 42 0.00 (111) Primitive cubic system Cu was deposited for 4 s from 0.025 M CuSO4·5H2O + 0.005 M HF aqueous solution. We suppose that the limited number of broken bonds of the Si (100) surface causes incomplete reduction of Cu2+ to Cu+ in some places. Thus, oxygen from the environment has an opportunity to give its electrons to Cu+ that is connected with the Si surface. Furthermore, correlation of such result with SEM allows us to conclude that the greater amount of Cu2O can be due to larger sizes of Cu particles. EBSD technique allows the revealing of orientation of the crystalline phase. It is provided by the stereographic projection of crystallographic directions, resulting in the creation of pole maps for the differently orientated crystals. Figure 4 presents the principle of the pole mapping where ND is for normal direction, TD is for transverse direction, and RD is for rolling direction. Figure 4a,c shows the reference spheres, and Figure 4b,d shows the projection planes.