Technologies for Improving the Operational Characteristics of Dynamic Gas-Liquid Thermal Power Plants with Controlled Laser Induction of Adjustable Local Configurations of Topological Microand Nanostructures on the Internal Metal Surface of Working Chambers. Раrt 2

The second part of the article presents a study and modeling of the electrophysical characteristics of parts with various purposes featuring a specific laser-induced configuration of microand nanostructural surface features on the product. The relevance of this study is due to the fact that during the operation of any power plant, the values of its electrophysical cha-racteristics are an integral part of it. The conducted research enables control over these chara-cteristics both in the input platform for power supply from corresponding generators to the installation and in the output energy used to ensure the operation of respective units, whose power supply is provided by energy installations of different classes during their operation in required modes, including extreme dynamic operating modes. This study specifically addresses demonstration circuits with prototypes of systems using microscrolls of 1D titanium dioxide structures in metal-carbon compounds (carbon – gold) under C–Au chain doping conditions. In this case, a three-stage process was implemented using laser ablation from a titanium target, synthesizing a thin porous titanium dioxide film and depositing it onto a demonstration quartz glass substrate. Subsequently, linear carbon chains, stabilized by gold nanoparticles at their edges, were introduced into the porous titanium dioxide film matrix by jet spraying, forming an array of microscrolls through mechanical action. Mathematical and computer modeling of topological microand nanostructures on the surfaces of metal complexes with laser-controlled configurations was performed. The conducted analysis allows us to draw a conclusion, based on the proposed procedures and processes regulating the topological structure of the considered surface objects during their laser synthesis, about the prospects of this direction, which is associated with the possibility of controlling the functional surface characteristics in the required direction, particularly regarding their electrophysical para-meters for various products used in energy devices.

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