Effect of functional groups on tribological properties of lubricants and mechanism investigation

Yu, Han‐Qing; Chen, Haijie; Zheng, Zhiwen; Qiao, Dan; Duan, Feng; Gong, Zhenbin

doi:10.1007/s40544-022-0630-9

Cited by 27 publications

(10 citation statements)

References 53 publications

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“…However, pure MEA molecules, due to their lack of charge and weaker interaction with the substrate, cannot form a regular and dense molecular brush structure on the substrate, resulting in higher friction coefficients. At the same time, the stronger interaction between anions with negatively charged carboxylate groups and the substrate also makes carboxylate groups more prone to tribochemical reactions under shear stress and Hertz contact stress, forming a carbon-based tribofilm, which better protects the worn surface and brings lower wear than pure MEA solutions …”

Section: Resultsmentioning

confidence: 99%

CO₂ Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication

Yu,

Zuo,

Zhang

et al. 2024

ACS Sustainable Chem. Eng.

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The capture and conversion of CO 2 are of great significance for mitigating the greenhouse effect and achieving sustainable development. Unlike previous CO 2 utilization methods, this work develops a novel CO 2 utilization strategy that directly converts captured CO 2 to a carbon-based tribofilm through in situ tribochemical reactions. Monoethanolamine (MEA) aqueous solution is used as the absorbent for CO 2 capture, and tribological experiments have shown that its lubrication performance is significantly enhanced under various loads and speeds after absorbing CO 2 . After absorbing CO 2 for 40 min, the friction and wear of 75 wt % MEA solution are decreased by 45.31 and 40.38%, respectively, compared to the unabsorbed MEA solution. The CO 2 undergoes a chemical reaction with MEA to produce carbamates. Anions of carbamates adsorb onto the substrate through carboxylate groups to form a molecular brush structure, decreasing friction coefficient. Meanwhile, the strong interaction between carboxylate groups and the substrate also makes carboxylate groups prone to tribochemical reactions, forming a carbon-based tribofilm and reducing wear. This work successfully achieves green lubrication by converting CO 2 into carboxylate groups, which are further in situ converted into carbon-based tribofilms through tribochemical reactions. This study not only reveals the potential value of CO 2 in tribology but also opens up a new path for the value-added utilization of CO 2 .

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Section: Resultsmentioning

confidence: 99%

CO₂ Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication

Yu,

Zuo,

Zhang

et al. 2024

ACS Sustainable Chem. Eng.

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“…In particular, a CoF of 0.120 was obtained with a 1.5 wt.% concentration of oleic acid, compared to the reference value of 0.149. This behavior is explained by the absorption of the additive molecule on the steel surfaces, which leads to a lower friction coefficient, and thus, a higher additive concentration [ 45 ].…”

Section: Resultsmentioning

confidence: 99%

Study of the Effect of ZnO Functionalization on the Performance of a Fully Formulated Engine Oil

Hernaiz,

Elexpe,

Aranzabe

et al. 2023

Nanomaterials

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The automotive sector is demanding higher specifications to achieve maximum efficiency; in this sense a new generation of lubricants with higher thermo-oxidative stability and superior tribological properties is being explored. The formulation of nanolubricants based on the nature of different nanomaterials is one of the most recent approaches, with several gaps to cover, such as dispersion stability, related to the compatibility of proposed nanomaterials with conventional additives and baseoils used in lubricant formulation. This study evaluated the effect of ZnO nanomaterial dispersed in a commercial engine oil using two different approaches; the use of surfactant and nanomaterial surface functionalization to promote higher stability and lower cluster size. Experimental evidence shows a synergetic effect between the tribological protection mechanism and the antioxidant properties in the lubricant. The effect of nanoparticle cluster size, functionalization level, and nanomaterial content are presented.

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“…7(a-d). The adsorption energy between the base oil and additive lubrication systems with the metal α-Fe 2 O 3 substrate was calculated according to formula (1) to characterize the interaction between the metal substrate and lubricant molecules [22,25]. E adsroption is the adsorption energy between lubricant molecules and Fe 2 O 3 substrate.…”

Section: Molecular Dynamics Simulationsmentioning

confidence: 99%

“…and hydrocarbon tail chain differences (chain length, saturation, etc.) dominate the tribological characteristics [23][24][25][26].…”

Section: Introduction E Cient Lubrication Can Effectively Reduce Ener...mentioning

confidence: 99%

“…Attributed to the formation of a bilayer structure consisting of a chemisorbed layer and a hydrogen bonding network layer on the metal surface by polar head groups. Yu et al [25] explored the in uence of functional group differences of nine additives on tribological properties through friction experiments and DFT calculation. The results indicate that acid additives with carboxyl functional groups exhibit the best friction reduction and antiwear properties, attributed to greater adsorption and surface energy exhibited by the acid additives on metal surfaces.…”

Section: Introduction E Cient Lubrication Can Effectively Reduce Ener...mentioning

confidence: 99%

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On the Structure–Activity Relationship of Glyceryl oleate Friction Modifiers and Its Synergistic Mechanism on Phosphate ester Antiwear Additives

et al. 2023

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The structure-activity relationship of glyceryl oleate organic friction modi ers and the difference in interaction with antiwear additives signi cantly affect the friction and wear characteristics of the lubrication system. This paper comprehensively considers the differences between polar functional groups and hydrocarbon tail chains, a combination of experiments and simulations were used to investigate the structure-activity relationships of three glyceryl oleate friction modi ers and the synergistic antiwear mechanisms with phosphate ester additives. The results indicate that the reduction of hydroxyl groups in glyceryl oleate weakens the electrostatic interaction with the metal interface and hydrogen bonding interaction, and the increase in hydrocarbon tail chains leads to the enhancement of the steric hindrance effect. Resulting in the substitution of polar functional groups and the increase in hydrocarbon tail chains deteriorating tribological properties. In addition, the binary additive system of glyceryl monooleate and phosphate ester exhibits a signi cant synergistic antiwear effect. It is attributed to the chemisorption of additive O(C = O/P-O/P = O) active sites and the Fe 2 O 3 metal interface, GMO hydrogen bond interactions, the deprotonation of phosphate ester, as well as the carbonate and phosphate protective lm generated by tribochemical reaction.

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Effect of functional groups on tribological properties of lubricants and mechanism investigation

Cited by 27 publications

References 53 publications

CO₂ Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication

CO₂ Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication

Study of the Effect of ZnO Functionalization on the Performance of a Fully Formulated Engine Oil

On the Structure–Activity Relationship of Glyceryl oleate Friction Modifiers and Its Synergistic Mechanism on Phosphate ester Antiwear Additives

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Effect of functional groups on tribological properties of lubricants and mechanism investigation

Cited by 27 publications

References 53 publications

CO2 Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication

CO2 Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication

Study of the Effect of ZnO Functionalization on the Performance of a Fully Formulated Engine Oil

On the Structure–Activity Relationship of Glyceryl oleate Friction Modifiers and Its Synergistic Mechanism on Phosphate ester Antiwear Additives

Contact Info

Product

Resources

About

CO₂ Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication

CO₂ Capture and Conversion into Carbon-Based Tribofilm by In Situ Tribochemical Reaction for Green Lubrication