DOI: 10.18503/1995-2732-2021-19-2-68-78
Abstract
Problem Statement (relevance of the research). The variety of different types of surface damage to materials in the operation of vehicles and mechanisms contributes to current relevance of basic and applied research on the creation of new wear-resistant materials. Improving the nanostructured topocomposites by creating additional, locally dissipative structural elements is the most promising direction for creating a new type of nanostructured topocomposites with cluster-gradient architecture. Methods Applied. An improved unit was used to carry out ion-plasma and ion-beam processing under conditions of a discrete and varying front. Novelty. Studies of the evolution of the coating structure were carried out depending on the conditions of ion-vacuum processing. The authors established the effects of "stratification" of the cluster phase and texturing of the condensed phase during ion-plasma sputtering. They tested the technological solutions combining selective ion processing, ion assistance and coating deposition to form the required topocomposite surface structure. The change in the coating phase composition along depth was studied. Result. It was found that during combined ion-vacuum processing, titanium oxynitrides are formed in the "coating-base" interface. This paper presents results of the formation of nanostructured topocomposites with cluster-gradient architecture. Practical significance. It is shown that these phases along with the cluster morphology of topocomposites are positive factors contributing to an increase in wear resistance under severe conditions of temperature-dynamic loading, when cutting a difficult-to-machine nickel alloy.
Keywords
Ion-plasma processing, ion-beam processing, nanostructured topocomposites with cluster-gradient architecture, cluster phase, nanocluster morphology.
For citation
Poleshchenko K.N., Korotaev D.N., Eremin E.N., Nesov S.N., Tarasov E.E., Teploukhov A.A., Semenyuk N.A., Ivanova E.V., Lasitsa A.M., Ivanov A.L. Formation of Nanostructured Topocomposites with Cluster-Gradient Architecture by Combined Ion-Vacuum Processing. Vestnik Magnitogorskogo Gosudarstvennogo Tekhnicheskogo Universiteta im. G.I. Nosova [Vestnik of Nosov Magnitogorsk State Technical University]. 2021, vol. 19, no. 2, pp. 68–78. https://doi.org/10.18503/1995-2732-2021-19-2-68-78
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