Thermal stability of Si/SiC/ta-C composite coatings and improvement of tribological properties through high-temperature annealing

Jang, Young-Soo; Kim, Jae-Il; Kim, Won-seok; Kim, Do Hyun; Jong-Kuk, Kim

doi:10.1038/s41598-022-07514-8

Cited by 11 publications

(4 citation statements)

References 43 publications

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“…Although some authors point out that the flash temperature is not high in the super-lubricated state of DLC, , the formation of dangling bonds by the wear and shear process provides support for sp 2 bonding even at low flash temperatures. Some researchers argued that the frictional heat of DLC in a frictionless state was calculated by less than 10 °C at the contact spot. ,, Therefore, since the graphitization of DLC starts at more than 300 °C, , the structural change by friction-induced temperature rise can be a little welcome individually under the superlubricity state. The flash temperature or hot-spot temperature promotes the chemical reaction; however, we infer it is not essential for structural evolution.…”

Section: Resultsmentioning

confidence: 99%

“…Some researchers argued that the frictional heat of DLC in a frictionless state was calculated by less than 10 °C at the contact spot. 71,94,95 Therefore, since the graphitization of DLC starts at more than 300 °C, 96,97 the structural change by friction-induced temperature rise can be a little welcome individually under the superlubricity state. The flash temperature or hot-spot temperature promotes the chemical reaction; however, we infer it is not essential for structural evolution.…”

Section: Deep Insights Into Shear-induced Structural Transformationmentioning

confidence: 99%

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Superlubricity with Graphitization in Ti-Doped DLC/Steel Tribopair: Response on Humidity and Temperature

Kim

Lee

Tokoroyama

et al. 2023

ACS Appl. Mater. Interfaces

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The anti-friction of diamond-like carbon (DLC) is achieved by a well-developed carbonaceous transfer layer, and Ti-doped DLC is developed into a robustly built-up carbonaceous transfer layer. The friction performance of DLC depends on the operating environment, e.g., ambient gas, humidity, temperature, lubricants, and mating material. In this study, we aimed to reveal the environmental sensitivities of Ti-DLC on friction characteristics. To this end, a Ti-DLC was rubbed against a steel ball, and friction behaviors were evaluated with different gas compositions, humidity, and temperature. Finally, we identified that fractional coverage of water on surfaces affected the anti-graphitization on Ti-DLC, leading to avoiding friction reduction.

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Section: Resultsmentioning

confidence: 99%

Section: Deep Insights Into Shear-induced Structural Transformationmentioning

confidence: 99%

Superlubricity with Graphitization in Ti-Doped DLC/Steel Tribopair: Response on Humidity and Temperature

Kim

Lee

Tokoroyama

et al. 2023

ACS Appl. Mater. Interfaces

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“…In recent years, numerous research reports have been made available on different hard coatings for elevated temperature tribological applications [14][15][16][17][18]. The tribological behavior of the coating under HT conditions is evidently different from that under room temperature conditions.…”

Section: Coating Contact/failure Mechanisms At Elevated Temperaturesmentioning

confidence: 99%

State-of-the-Art Developments in Advanced Hard Ceramic Coatings Using PVD Techniques for High-Temperature Tribological Applications

2023

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Hard and wear-resistant coatings created utilizing physical vapor deposition (PVD) techniques are extensively used in extreme tribological applications. The friction and wear behavior of coatings vary significantly with temperature, indicating that advanced coating concepts are essential for prolonged load-bearing applications. Many coating concepts have recently been explored in this area, including multicomponent, multilayer, gradient coatings; high entropy alloy (HEA) nitride; and functionally modified coatings. In this review, we highlighted the most significant findings from ongoing research to comprehend crucial coating properties and design aspects. To obtain enhanced tribological properties, the microstructure, composition, residual stress, hardness, and HT oxidation resistance are tuned through doping or addition of appropriate materials at an optimized level into the primary coatings. Such improvements are achieved by optimizing PVD process parameters such as input power, partial pressure, reactive gas flow rates, substrate bias, and temperature. The incorporation of ideal amounts of Si, Cr, Mo, W, Ag, and Cu into ternary and quaternary coatings, as well as unique multilayer designs, considerably increases the tribological performance of the coatings. Recent discoveries show that not only mechanical hardness and fracture toughness govern wear resistance, but also that oxidation at HT plays a significant role in the lubrication or wear failure of coatings. The tribo-induced metal oxides and/or Magnéli phases concentrated in the tribolayer are the key governing factors of friction and wear behavior at high temperatures. This review includes detailed insights into the advancements in wear resistance as well as various failure mechanisms associated with temperature changes.

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“…From the past to the present, hard coatings have been a very important technology in the industrial field due to their tribological performance as well as cost efficiency. In recent years, DLC (diamond-like carbon) has become one of the hottest topics in the field of tribology due to its low friction [8][9][10][11], high hardness [12][13][14], wear resistance [15][16][17][18], and thermal stabilities [19][20][21]. The uniqueness of DLC, which dramatically changes its carbonaceous structure to sp 2 rich structure [22][23][24][25], can be viewed as an important concept of passive control of friction by frictional stimuli.…”

Section: Introductionmentioning

confidence: 99%

Active control of Lubricant Flow Using Dielectrophoresis and Its Effect on Friction Reduction

Murashima,

Aono,

Umehara

et al. 2023

Tribology Online

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With the increasing demand for active friction control, we newly proposed to use dielectrophoresis to change the flow of PG-dropletcontaining PAO4 to reduce the friction coefficient. The friction result with a 1-mm roller shows 20% reduction in friction coefficient (from 0.065 to 0.052) at AC 100 V, and in situ observation exhibits that PG tracks are formed over the contact area. On the other hand, at a high bias of 1000 V, the friction coefficient increases to 0.065. In this situation, in situ observation exhibits that PG forms a horseshoeshaped track covering only the roller edges. Controlled friction tests and FEM analysis using 5-mm rollers revealed a unique behavior; a balanced bias effectively attracts the PG to the roller surface, and surface forces can resist mild dielectrophoretic forces to spread the PG across the roller surface. The present study strongly suggests the importance that the bias strength should be controlled to achieve a balance between surface force and dielectrophoretic force in order to obtain excellent lubrication conditions.

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Thermal stability of Si/SiC/ta-C composite coatings and improvement of tribological properties through high-temperature annealing

Cited by 11 publications

References 43 publications

Superlubricity with Graphitization in Ti-Doped DLC/Steel Tribopair: Response on Humidity and Temperature

Superlubricity with Graphitization in Ti-Doped DLC/Steel Tribopair: Response on Humidity and Temperature

State-of-the-Art Developments in Advanced Hard Ceramic Coatings Using PVD Techniques for High-Temperature Tribological Applications

Active control of Lubricant Flow Using Dielectrophoresis and Its Effect on Friction Reduction

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