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Information × Registration Number 0205U007028, 0105U005730 , R & D reports Title Development and verification of some components of a model predicting behaviour of FCM in object "Shelter" popup.stage_title Head Mryglod Igor Myronovych, Registration Date 08-12-2005 Organization Institute for Condensed Matter Physics of the National Academy of Sciences of Ukraine popup.description2 The report includes of 194 pages of the copying text and contains the introduction, five chapters of main part, introduction and list of 267 references. There are 60 pictures and 15 tables. The model based on the conception of distributed potential barrier are stated for the description of the electrical properties of LFCM. This model allow to describe quantitatively frequency dependences of permittivity, dielectric losses of LFCM and static volume conductivity of these materials too in wide temperature region (from 270 to 1000K). It was proposed to carry out the chain of experiments in order to get more exact forming mechanism of dielectric and magnetic properties of these materials. Original method for computer simulation of longtime dynamics of submicron breeze in air space was developed. The dependence of such particles features on their sizes and force fields influences are indicated. It was studied conditions of charging of breeze particles by laser and X-ray radiation in OS. Estimationsof optimal diapasons of electric fields where charging processes are most effective are carried out. It was shown that process of charging of submicron breeze particles useful increases the activity of coagulation these particles with particles of the liquid neutral aerosol of the micron range. This phenomenon can be used for breeze particles utilization in OS. It was also shown that quite strong dipole-dipole interaction which stimulates the process of particles flocculation can appear as result of adsorption of particles with dipole moment. On the base analysis of phenomenological models it is investigated influence of radiation defect creation on the mechanical properties of these materials. The phase behaviour of glass-like elements of LFCM is investigated. It is shown that including of large part of phases into amorphous LFCM lead to destruction processes in these materials. Product Description popup.authors popup.nrat_date 2020-04-02 Close