Towards developing robust solid lubricant operable in multifarious environments

Ayyagari, Aditya; Mutyala, Kalyan C.; Sumant, Anirudha V.

doi:10.1038/s41598-020-72666-4

Cited by 34 publications

(15 citation statements)

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“…A higher A 1g intensity may be related to the better MoS 2 crystallinity in the tribofilm. 68 It can be clearly seen that the A 1g intensity of the irradiated No. 1 film decreases slightly in comparison to the unirradiated case, whereas the variation of A 1g intensity for the composite films before and after AO irradiation is negligible.…”

Section: ■ Results and Discussionmentioning

confidence: 94%

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MoS₂/WS₂ Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

Fan

Shi

Cui

et al. 2021

ACS Appl. Nano Mater.

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The atomic oxygen (AO) in the low earth orbit (LEO) has an irreversible degradation impact on the tribological properties of MoS 2 lubricating films widely used in space. Here, we demonstrate that high irradiation tolerance combined with low friction and wear can be realized at a composite comprising the MoS 2 matrix with a small amount of WS 2 . By comprehensively using microstructure characterization and molecular dynamics (MD) calculations, we reveal that the amorphous structure of a pure MoS 2 film is the most susceptible to be oxidized due to its loose and disordered structure. In comparison, films with a highly ordered (002) crystal plane parallel to the substrate can significantly inhibit the diffusion of AO, e.g., the oxidation depth of a MoS 2 /WS 2 composite film with an addition of 3.9 atom % WS 2 is below 20 nm after a dose of 5.4 × 10 19 atoms•cm −2 irradiation. Specifically, the structure of composite films during long-term AO irradiation experiences a transformation process from the MoS 2 crystal to the MoO x nanocrystal to amorphous. Compared with the rapid deterioration of tribological properties for the pure MoS 2 film, the MoS 2 /WS 2 composite film maintains a low friction coefficient of 0.015 and wear rate of 2.03 × 10 −7 mm 3 •N −1 •m −1 after a dose of 5.4 × 10 19 atoms•cm −2 irradiation, almost identical to the unirradiated samples.

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Section: ■ Results and Discussionmentioning

confidence: 94%

“…We measure the A 1g intensity of Raman spectra obtained from 15 different points identified on the rectangle in the wear scar (Figure h). A higher A 1g intensity may be related to the better MoS 2 crystallinity in the tribofilm . It can be clearly seen that the A 1g intensity of the irradiated No.…”

Section: Resultsmentioning

confidence: 99%

MoS₂/WS₂ Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

Fan

Shi

Cui

et al. 2021

ACS Appl. Nano Mater.

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“…6−8 However, MoS 2 tends to be oxidized by oxygen and water vapor in the atmospheric environment, which reduces the friction properties and shortens the wear life. 7,9 Research has shown that metal doping 9−11 is a simple and economical method to improve the mechanical and tribological properties of MoS 2 solid lubricating materials. Meanwhile, the construction of micro-/nanotexture surfaces can not only improve the bearing capacity as power bearings but can also increase the storage capacity of lubricating materials and prolong the service life.…”

Section: Introductionmentioning

confidence: 99%

“…MoS 2 , a typical two-dimensional (2D) layered transition-metal dichalcogenide, has been widely used as a solid lubricant in the aviation field because of the excellent vacuum lubrication performance induced by its high interlayer anisotropy. − However, MoS 2 tends to be oxidized by oxygen and water vapor in the atmospheric environment, which reduces the friction properties and shortens the wear life. , Research has shown that metal doping − is a simple and economical method to improve the mechanical and tribological properties of MoS 2 solid lubricating materials. Meanwhile, the construction of micro-/nanotexture surfaces can not only improve the bearing capacity as power bearings but can also increase the storage capacity of lubricating materials and prolong the service life. − On the other hand, the poor adhesion between MoS 2 and a matrix has always been a perplexing problem. − Inspired by mussel adhesion proteins, polydopamine (PDA) formed by self-polymerization of dopamine is a polymer with outstanding adsorption performances, which can be adsorbed on various materials through strong covalent and non-covalent bonds to serve as an effective protective layer for nanostructures. − In particular, the rich functional groups (e.g., −NH 2 , −OH and catechol groups) on the surface of PDA have strong chelating ability for transition-metal ions (e.g., Zn 2+ , Fe 3+ , and Mo 4+ ), − which is beneficial to provide a reaction platform as a nucleation site to form a unique solid core–shell structure, thus improving the adhesion and load-bearing capacity of the film.…”

Section: Introductionmentioning

confidence: 99%

Mussel-Inspired Interfacial Modification for Ultra-Stable MoS₂ Lubricating Films with Improved Tribological Behavior on Nano-Textured ZnO Surfaces Using the AACVD Method

Zhou

Wang

et al. 2022

ACS Appl. Mater. Interfaces

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Friction-associated energy loss and mechanical wear leading to failure is a major problem in industries. To mitigate this, the design and testing of novel lubricants is important. Here, we show the facile one-pot synthesis of ZnO/ZnO nanorods (NRs) and MoS2 films on pre-treated glass substrates via aerosol-assisted chemical vapor deposition. The bearing capacity and wear life of ZnO film/ZnO NRs/MoS2 films were improved due to the lubricant retention capabilities of the NRs. Modification of the ZnO/MoS2 nano-arrays using polydopamine (PDA) allowed the realization of robust and ultra-stable solid lubricants through the triple action of chemical chelation, layered materials, and nanotexture, especially under heavy load conditions. Compared with pristine MoS2, the adhesion and bearing strength of the composite film increased by 11 and 30 times, respectively, while the coefficient of friction and wear rate decreased by 94 and 85%, respectively. This is because the chelation between the transition metal and the groups in the interlayer PDA was fully utilized to improve the interface compatibility, which significantly improves the robustness of ZnO NRs and the adhesion of MoS2. This allowed a stable and firm mechanical lock between the substrate, lubricant films, and the steel ball. It demonstrated a convenient method to achieve the antifriction and anti-wear of solid lubricating materials by PDA interface modification for practical industrial applications.

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“…FIGURE 9 | Passivation of MoS 2 flakes by encapsulation with protective graphene oxide sheets. Reprinted with permission from(Ayyagari et al, 2020).…”

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confidence: 99%

Progress in Superlubricity Across Different Media and Material Systems—A Review

et al. 2022

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Superlubricity is a terminology often used to describe a sliding regime in which the adhesion leading to friction or resistance to sliding literally vanishes. For improved energy security, environmental sustainability, and a decarbonized economy, achieving superlubric sliding surfaces in moving mechanical systems sounds very exciting, since friction adversely impacts the efficiency, durability, and environmental compatibility of many moving mechanical systems used in industrial sectors. Accordingly, scientists and engineers have been exploring new ways to achieve macroscale superlubricity through the use of advanced materials, coatings, and lubricants for many years. As a result of such concerted efforts, recent developments indicate that with the use of the right kinds of solids, liquids, and gases on or in the vicinity of sliding contact interfaces, one can indeed achieve friction coefficients well below 0.01. The friction coefficient below this threshold is commonly termed the superlubric sliding regime. Hopefully, these developments will foster further research in the field of superlubricity and will ultimately give rise to the industrial scale realization of nearly-frictionless mechanical systems consuming far less energy and causing much-reduced greenhouse gas emissions. This will ultimately have a substantial positive impact on the realization of economically and environmentally viable industrial practices supporting a decarbonized energy future. In this paper, we will provide an overview of recent progress in superlubricity research involving solid, liquid, and gaseous media and discuss the prospects for achieving superlubricity in engineering applications leading to greater efficiency, durability, environmental quality, and hence global sustainability.

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Towards developing robust solid lubricant operable in multifarious environments

Cited by 34 publications

References 50 publications

MoS₂/WS₂ Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

MoS₂/WS₂ Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

Mussel-Inspired Interfacial Modification for Ultra-Stable MoS₂ Lubricating Films with Improved Tribological Behavior on Nano-Textured ZnO Surfaces Using the AACVD Method

Progress in Superlubricity Across Different Media and Material Systems—A Review

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Towards developing robust solid lubricant operable in multifarious environments

Cited by 34 publications

References 50 publications

MoS2/WS2 Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

MoS2/WS2 Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

Mussel-Inspired Interfacial Modification for Ultra-Stable MoS2 Lubricating Films with Improved Tribological Behavior on Nano-Textured ZnO Surfaces Using the AACVD Method

Progress in Superlubricity Across Different Media and Material Systems—A Review

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MoS₂/WS₂ Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

MoS₂/WS₂ Nanosheet-Based Composite Films Irradiated by Atomic Oxygen: Implications for Lubrication in Space

Mussel-Inspired Interfacial Modification for Ultra-Stable MoS₂ Lubricating Films with Improved Tribological Behavior on Nano-Textured ZnO Surfaces Using the AACVD Method