Synthesis of Nanocomposite TiSiCN Coatings by Titanium Evaporation and Organosilicon Compound Activation in Hollow Cathode Arc Discharge

Men’shakov, A. I.; Bruhanova, Yulia A; Kukharenko, Andrey I.

doi:10.3390/membranes12030321

Cited by 3 publications

(6 citation statements)

References 33 publications

(43 reference statements)

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“…The experiments were carried out in a discharge system based on a discharge with an SHHC, the scheme of which is shown in Figure 1, and the design of the system is described in detail in [28].…”

Section: Methodsmentioning

confidence: 99%

“…The disadvantages above describe the deprivation of obtaining coatings by reactive anodic evaporation of titanium and decomposition of an OSC precursor in a discharge with a self-heating hollow cathode (SHHC). The possibility of obtaining TiSiCN coatings by the proposed method was realized in [28], where the results of the first experiments are presented, showing the fundamental possibility of obtaining nanocomposite TiSiCN coatings by this method. In such a discharge, a high-density plasma is created without using a separate source of vapor-gas mixture ionization, and filtration systems are not used, since there are no microdrops in the vaporized metal stream.…”

Section: Introductionmentioning

confidence: 99%

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Plasma Enhanced High-Rate Deposition of Advanced Film Materials by Metal Reactive Evaporation in Organosilicon Vapors

et al. 2023

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Dense homogeneous nanocomposite TiSiCN coatings with a thickness of up to 15 microns and a hardness of up to 42 GPa were obtained by the method of reactive titanium evaporation in a hollow cathode arc discharge in an Ar + C2H2 + N2-gas mixture with the addition of hexamethyldisilazane (HMDS). An analysis of the plasma composition showed that this method allowed for a wide range of changes in the activation degree of all components of the gas mixture, providing a high (up to 20 mA/cm2) ion current density. It is possible to widely change the chemical composition, microstructure, deposition rate, and properties of coatings obtained by this method, by changing the pressure, composition, and activation degree of the vapor–gas mixture. An increase in the fluxes of C2H2, N2, HMDS, and discharge current leads to an increase in the rate of coating formation. However, the optimal coatings from the point of view of microhardness were obtained at a low discharge current of 10 A and relatively low contents of C2H2 (1 sccm) and HMDS (0.3 g/h), exceeding which leads to a decrease in the hardness of the films and the deterioration of their quality, which can be explained by the excessive ionic exposure and the non-optimal chemical composition of the coatings.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Plasma Enhanced High-Rate Deposition of Advanced Film Materials by Metal Reactive Evaporation in Organosilicon Vapors

et al. 2023

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“…The studies were carried out on the installation schematically shown in Figure 1. The design of the gas discharge system and the experimental scheme are described in detail in [4]. The gas discharge system is equipped with a hollow cylindrical cathode made of TiN powder by magnetic pulse pressing and a sectional anode.…”

Section: Experimental Methodsmentioning

confidence: 99%

“…They may have excellent performance characteristics, but the properties of these coatings are determined mainly by the conditions of their synthesis. In [4], a method for obtaining TiSiCN coatings by anodic evaporation of titanium and decomposition of hexamethyldisilazane (HMDS) in hollow cathode arc discharge was described. The advantage of this method is the ability to independently change various deposition conditions over a wide range, in particular the metal vapor flow, discharge current, composition and pressure of the gas mixture.…”

Section: Introductionmentioning

confidence: 99%

Influence of parameters of the discharge with a self-heating hollow cathode and a sectional anode on the activation degree of a vapor-gas medium

Men’shakov¹,

Bryukhanova²

2022

8th International Congress on Energy Fluxes and Radiation Effects

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The composition of a discharge plasma with a self-heating hollow cathode and a sectional anode including an evaporated titanium anode has been studied by optical emission spectroscopy. The effect of discharge parameters on the activation degree of a vapor-gas medium including argon, titanium vapor, hexamethyldisilazane vapor, as well as reactive gases nitrogen and acetylene is investigated. It is shown that by changing the discharge parameters it is possible to change the plasma composition within a wide range, in particular, the fraction and degree of ionization of Ti vapors, the dissociation degree of nitrogen and acetylene.

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“…To obtain binary coatings by reactive evaporation, arcs with a self-heating hollow cathode (SHC) are used, which are able to function stably for a long time under conditions of pumping an inert gas (or N2) through the cathode cavity and supplying the reaction gas to the discharge gap [2], both in continuous and pulse-periodic (10-1000 Hz, 10-100 ms) modes [3]. Oxide [4], nitride [5], and composite [6] coatings are obtained by reaction anode evaporation in a discharge with SHC at a rate of more than 1 μm/h.…”

Section: Introductionmentioning

confidence: 99%

Diagnostics of a low-pressure arc plasma (N2, 0.1–1 Pa) in the mode of aluminum anodic evaporation

Ershov¹,

Kamenetskikh²

2022

8th International Congress on Energy Fluxes and Radiation Effects

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The use of an arc with a thermionic cathode burning in vapors of the anode material for the coating deposition provides high deposition rates, a controlled level of ion assistance, and the absence of microdroplets characteristic of a cathode arc. The use for this purpose of a low-pressure arc with a self-heating hollow cathode makes it possible to use an active gaseous medium for the synthesis of binary coatings, for example, nitride or oxide coatings. The rate of deposition of such coatings, their structure, and properties depend on such parameters of the discharge plasma as the plasma density and its electron temperature, the anode potential drop, the mass composition of the plasma, the degree of vapor ionization, and the degree of reactive gas dissociation. In this work, to diagnose the discharge plasma, probe diagnostics and optical emission spectroscopy were used. The results of measurements obtained in wide ranges of discharge current (5–30 A), reactive gas pressure (N2, 0.1–1 Pa), and evaporation rate of Al ((1.4–18)·10-5 g/cm2·s) are presented.

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Synthesis of Nanocomposite TiSiCN Coatings by Titanium Evaporation and Organosilicon Compound Activation in Hollow Cathode Arc Discharge

Cited by 3 publications

References 33 publications

Plasma Enhanced High-Rate Deposition of Advanced Film Materials by Metal Reactive Evaporation in Organosilicon Vapors

Plasma Enhanced High-Rate Deposition of Advanced Film Materials by Metal Reactive Evaporation in Organosilicon Vapors

Influence of parameters of the discharge with a self-heating hollow cathode and a sectional anode on the activation degree of a vapor-gas medium

Diagnostics of a low-pressure arc plasma (N2, 0.1–1 Pa) in the mode of aluminum anodic evaporation

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