Abstract:
The micro- and nanoreliefs of loaded lateral surfaces and fracture surfaces of foils of the Fe$_{77}$Ni$_1$Si$_9$B$_{13}$, Fe$_{58}$Ni$_{20}$Si$_9$B$_{13}$ and Fe$_{70}$Cr$_{15}$B$_{15}$ amorphous alloys have been investigated using scanning tunneling and atomic force microscopy. The isotropic and anisotropic surface reliefs have been examined. The fractal dimensions of the surfaces of loaded specimens and the fracture surfaces along and across the direction of crack propagation have been estimated using the box counting method. Fractal characteristics of the surfaces, such as the Hölder exponent and the half-width of the singularity spectrum, have been calculated using the wavelet transform method. It has been found that, on the topographies with a clearly pronounced anisotropy of the relief, the surface is fractal in only one direction, and the surface is fractal in two directions on the topographies with a less pronounced anisotropy of the relief. The fractal characteristics of the lateral surfaces and the fracture surfaces with allowance made for their anisotropy have close values. It has been shown that the formation of two types of fracture surfaces is adequately described in terms of the model of a cellular automaton.
Fulltext:
PDF file (1028 kB)
