Ultralow Macroscale Friction and Wear of MoS<sub>2</sub> in High‐Vacuum Through DC Pulsing Optimization, Nitridization, and Sublayer Engineering

Khadem, Mahdi; Hwang, Youn‐Hoo; Penkov, Oleksiy V.; Kim, Dae Eun

doi:10.1002/admi.202201412

Cited by 4 publications

(2 citation statements)

References 54 publications

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“…In-depth research by scholars from various countries has made great progress, solid superlubricity and liquid superlubricity materials have been widely tapped, and many emerging materials have also joined the study of superlubricity, such as black phosphorus, the Mxenes family, etc. ; many classical superlubricity materials have also been explored and new systems have been developed; and high-temperature superlubricity and solid-liquid combined superlubricity have also achieved very significant research results [197][198][199][200][201]. In this article, we introduce the origin and concept of superlubricity to give readers a clear understanding of the importance of superlubricity; categorize and overview the domestic and international research progress of superlubricity; and explore the generation mechanism of various types of superlubricity in the hope of discovering universally applicable mechanisms from a wide range of superlubricity designs.…”

Section: Discussionmentioning

confidence: 99%

A Systematic Review of the Recent Advances in Superlubricity Research

Zeng,

Zhang

2023

Coatings

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Friction and the wear caused by friction will not only lead to energy dissipation, but will also cause damage to the function of mechanical parts, affecting the precision and lifespan of mechanical devices. Superlubricity as an ideal state of zero friction has become a hot research topic in recent years. There have been many reviews on the concept, origin, and research progress of superlubricity, but, among them, there are more presentations on the research status of solid superlubricity and liquid superlubricity; however, the theoretical summarization of solid–liquid combined superlubricity and high-temperature superlubricity is still imperfect and lacks a systematic and comprehensive review. The mechanism of superlubricity is not explicitly presented in many reviews, which are clearly summarized in this paper. This paper introduces superlubricity from friction, and then introduces the origin of superlubricity, and presents the research progress on superlubricityby separating it into in four categories: liquid superlubricity, solid superlubricity, solid–liquid combined superlubricity, and high-temperature superlubricity. By analyzing the superlubricity system, the mechanism of realizing various types of superlubricity, such as incommensurability, hydration, and oxidation, is summarized. Based on the research progress of superlubricity, the development prospects, opportunities, and challenges of superlubricity in the future are discussed.

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Section: Discussionmentioning

confidence: 99%

A Systematic Review of the Recent Advances in Superlubricity Research

Zeng,

Zhang

2023

Coatings

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“…Therefore, a lot of research and development has been done on solid lubricant materials to enhance friction reduction and anti-wear performance, boosting the reliability and effectiveness of tribological systems [4,5]. The remarkable lubricating characteristics of transition metal dichalcogenides (TMDs) in high vacuum and high temperature settings have led to their emergence as representative solid lubricants and their widespread application in the field of space engineering during the past several decades [6][7][8][9][10]. The superior tribological properties of TMDs stem from their unique structure [11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Dual in-situ observation of tribochemical and morphological evolution of single-layer WS2 and multi-layer WS2/C coatings

Liu,

Han,

et al. 2024

Friction

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The outstanding tribological performance of transition metal dichalcogenides (TMDs) is attributed to their unique sandwich microstructure and low interlayer shear stress. This advantageous structure allows TMDs to demonstrate exceptional friction reduction properties. Furthermore, the incorporation of TMDs and amorphous carbon (a-C) in multi-layer structures shows excellent potential for further enhancing tribological and anti-oxidation properties. Amorphous carbon, known for its high ductility, chemical inertness, and excellent wear resistance, significantly contributes to the overall performance of these multi-layer coatings. To gain an in-depth understanding of the tribological mechanism and evolution of TMDs’ multi-layer coatings, a dual in-situ analysis was carried out using a tribometer equipped with a 3D laser microscope and a Raman spectrometer. This innovative approach allowed for a comprehensive evolution of the tribological, topographical, and tribochemical characteristics of both single-layer WS2 and multi-layer WS2/C coatings in real time. The findings from the dual in-situ tribotest revealed distinct failure characteristics between the single-layer WS2 coating and the multi-layer WS2/C coating. The single-layer WS2 coating predominantly experienced failure due to mechanical removal, whereas a combination of mechanical removal and tribochemistry primarily influenced the failure of the multi-layer WS2/C coating. The tribological evolution process of these two coatings can be classified into four stages on the basis of their tribological behavior: the running-in stage, stable friction stage, re-deposition stage, and lubrication failure stage. Each stage represents a distinct phase in the tribological behavior of the coatings and contributes to our understanding of their behavior during sliding.

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Degradation behavior of DLC thin film under gamma-rays irradiation using molecular dynamics simulation

Kang,

Seo,

Kim

2024

Diamond and Related Materials

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Ultralow Macroscale Friction and Wear of MoS₂ in High‐Vacuum Through DC Pulsing Optimization, Nitridization, and Sublayer Engineering

Cited by 4 publications

References 54 publications

A Systematic Review of the Recent Advances in Superlubricity Research

A Systematic Review of the Recent Advances in Superlubricity Research

Dual in-situ observation of tribochemical and morphological evolution of single-layer WS2 and multi-layer WS2/C coatings

Degradation behavior of DLC thin film under gamma-rays irradiation using molecular dynamics simulation

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Ultralow Macroscale Friction and Wear of MoS2 in High‐Vacuum Through DC Pulsing Optimization, Nitridization, and Sublayer Engineering

Cited by 4 publications

References 54 publications

A Systematic Review of the Recent Advances in Superlubricity Research

A Systematic Review of the Recent Advances in Superlubricity Research

Dual in-situ observation of tribochemical and morphological evolution of single-layer WS2 and multi-layer WS2/C coatings

Degradation behavior of DLC thin film under gamma-rays irradiation using molecular dynamics simulation

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Product

Resources

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Ultralow Macroscale Friction and Wear of MoS₂ in High‐Vacuum Through DC Pulsing Optimization, Nitridization, and Sublayer Engineering