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Ethanol has emerged as a promising alternative to fossil fuels, but its use can lead to significant dilution in lubricants, particularly during cold start or heavy traffic. This dilution can affect the performance of additives, including friction modifiers like molybdenum dithiocarbamate (MoDTC), which are designed to reduce friction under extreme contact conditions. Prior research suggests that ethanol may impact the performance of MoDTC, prompting this study’s goal to investigate the effects of ethanol on MoDTC tribofilms and their friction response under boundary lubrication conditions. Therefore, reciprocating tribological tests were performed with fully formulated lubricants containing MoDTC with varying ethanol concentrations. The results indicate that a critical ethanol dilution level inhibits friction reduction by MoDTC activation, resulting in friction coefficients (COFs) similar to the base oil. Surfaces tested with simple mixtures of polyalphaolefin (PAO) + MoDTC showed increased COFs with added ethanol. Analysis of tested surfaces using Raman spectroscopy, X-ray photoelectron spectroscopy (XPS), and X-ray absorption spectroscopy near the edge structure (XANES) revealed the presence of sulfates, MoO3, MoS2, and MoSxOy compounds in the tribofilms formed on the surfaces, with and without ethanol diluted in the lubricant. However, the addition of ethanol increased the sulfates and MoO3 content of the tribofilms at the expense of friction-reducing compounds such as MoS2 and MoSxOy. These findings suggest that ethanol dilution in lubricants containing MoDTC creates an oxygen-rich interfacial medium that favors the formation of compounds with insufficient friction-reducing capabilities.
Holmberg K, Andersson P, Erdemir A. Global energy consumption due to friction in passenger cars. Tribol Int 47: 221–234 (2012)
Graham J, Spikes H, Korcek S. The friction reducing properties of molybdenum dialkyldithiocarbamate additives: Part Ⅰ—Factors influencing friction reduction. Tribol Trans 44: 626–636 (2001)
Tang Z, Li S. A review of recent developments of friction modifiers for liquid lubricants (2007–present). Curr Opin Solid State Mater Sci 18: 119–39 (2014)
Spikes H. Friction modifier additives. Tribol Lett 60: 5 (2015)
Balarini R, Diniz G A S, Profito F J, Souza R M. Comparison of unidirectional and reciprocating tribometers in tests with MoDTC-containing oils under boundary lubrication. Tribol Int 149: 105686 (2020)
Vengudusamy B, Green J H, Lamb G D, Spikes H A. Behaviour of MoDTC in DLC/DLC and DLC/steel contacts. Tribol Int 54: 68–76 (2012)
Cousseau T, Ruiz Acero J S, Sinatora A. Tribological response of fresh and used engine oils: The effect of surface texturing, roughness, and fuel type. Tribol Int 100: 60–69 (2015)
Graham J, Spikes H, Jensen R. The friction reducing properties of molybdenum dialkyldithiocarbamate additives: Part Ⅱ—Durability of friction reducing capability. Tribol Trans 44: 637–647 (2001)
De Feo M, Minfray C, De Barros Bouchet M I, Thiebaut B, Le Mogne T, Vacher B, Martin J M. Ageing impact on tribological properties of MoDTC-containing base oil. Tribol Int 92: 126–135 (2015)
Khaemba D N, Jarnias F, Thiebaut B, Neville A, Morina A. The role of surface roughness and slide-roll ratio on the decomposition of MoDTC in tribological contacts. J Phys D Appl Phys 50: 085302 (2017)
Topolovec Miklozic K, Graham J, Spikes H. Chemical and physical analysis of reaction films formed by molybdenum dialkyl-dithiocarbamate friction modifier additive using Raman and atomic force microscopy. Tribol Lett 11: 71–81 (2001)
Yamamoto Y, Gondo S. Friction, and wear characteristics of molybdenum dithiocarbamate and molybdenum dithiophosphate. Tribol Trans 32: 251–257 (1989)
Khaemba D N, Neville A, Morina A. New insights on the decomposition mechanism of molybdenum dialkyldithioCarbamate (MoDTC): A Raman spectroscopic study. RSC Adv 6: 38637–38646 (2016)
Grossiord C, Varlot K, Martin J, Mogne T Le, Esnouf C. MoS2 single sheet lubrication by molybdenum. Tribol Int 31: 737–743 (1999)
Agarwal A K. Biofuels (alcohols and biodiesel) application as fuels for internal combustion engines. Prog Energy Combust Sci 33: 233–271 (2007)
Khuong L S, Zulkifli N W M, Masjuki H H, Mohamad E N, Arslan A, Mosarof M H, Azham A. A review on the effect of bioethanol dilution on the properties and performance of automotive lubricants in gasoline engines. RSC Adv 6: 66847–66869 (2016)
Costa H L, Cousseau T, Souza R M. Current knowledge on friction, lubrication, and wear of ethanol-fuelled engines—A review. Lubricants 11(7): 292 (2023)
Costa H L, Spikes H. Effects of ethanol contamination on friction and elastohydrodynamic film thickness of engine oils. Tribol Trans 58: 158–168 (2015)
Costa H L, Evangelista K S, Cousseau T, Acero J S R, Kessler F. Use of XANES and XPS to investigate the effects of ethanol contamination on anti-wear ZDDP tribofilms. Tribol Int 159: 106997 (2021)
Costa H L, Spikes H A. Impact of ethanol on the formation of antiwear tribofilms from engine lubricants. Tribol Int 93: 364–376 (2016)
Costa H L, Spikes H. Interactions of ethanol with friction modifiers in model engine lubricants. Lubricants 7: 1–17 (2019)
Sahoo S, Gaur A P S, Ahmadi M, Guinel M J F, Katiyar R S. Temperature-dependent Raman studies and thermal conductivity of few-layer MoS2. J Phys Chem C 117: 9042–9047 (2013)
Choi Y H, Cho J, Lunsford A M, Al-Hashimi M, Fang L, Banerjee S. Mapping the electrocatalytic activity of MoS2 across its amorphous to crystalline transition. J Mater Chem A 5: 5129–5141 (2017)
Gong Q, Cheng L, Liu C, Zhang M, Feng Q, Ye H, Zeng M, Xie L, Liu Z, Li Y. Ultrathin MoS2(1-x)Se2x alloy nanoflakes for electrocatalytic hydrogen evolution reaction. ACS Catal 5: 2213–2219 (2015)
Benoist L, Gonbeau D, Pfister-Guillouzo G, Schmidt E, Meunier G, Levasseur A. X-ray photoelectron spectroscopy characterization of amorphous molybdenum oxysulfide thin films. Thin Solid Films 258: 110–114 (1995)
De Barros’Bouchet M I, Martin J M, Le-Mogne T, Vacher B. Boundary lubrication mechanisms of carbon coatings by MoDTC and ZDDP additives. Tribol Int 38: 257–264 (2005)
Feo M De, Minfray C, Bouchet M I D B, Thiebaut B, Le T, Vacher B, Martin J M. Ageing impact on tribological properties of MoDTC-containing base oil. Tribol Int 92: 126–135 (2015)
Deshpande P, Minfray C, Dassenoy F, Thiebaut B, Le Mogne T, Vacher B, Jarnias F. Tribological behaviour of TiO2 atmospheric plasma spray (APS) coating under mixed and boundary lubrication conditions in presence of oil containing MoDTC. Tribol Int 118: 273–286 (2018)
Hui Z, Li Z, Ju P, Nie Y, Ouyang J, Tian Y. Comparative studies of the tribological behaviors and tribo-chemical mechanisms for AlMgB14-TiB2 coatings and B4C coatings lubricated with molybdenum dialkyl-dithiocarbamate. Tribol Int 138: 47–58 (2019)
Sgroi M, Gili F, Mangherini D, Lahouij I, Dassenoy F, Garcia I, Odriozola I, Kraft G. Friction reduction benefits in valve-train system using IF-MoS2 added engine oil. Tribol Trans 58: 207–214 (2015)
Seredych M, Wu C T, Brender P, Ania C O, Vix-Guterl C, Bandosz T J. Role of phosphorus in carbon matrix in desulfurization of diesel fuel using adsorption process. Fuel 92: 318–326 (2012)
Siow K S, Britcher L, Kumar S, Griesser H J. XPS study of sulfur and phosphorus compounds with different oxidation states. Sains Malays 47: 1913–1922 (2018)
De Barros M I, Bouchet J, Raoult I, Le Mogne T, Martin J M, Kasrai M, Yamada Y. Friction reduction by metal sulfides in boundary lubrication studied by XPS and XANES analyses. Wear 254: 863–870 (2003)
Pereira G, Lachenwitzer A, Kasrai M, Bancroft G M, Norton P R, Abrecht M, Gilbert P U P A, Regier T, Blyth R I R, Thompson J. Chemical and mechanical analysis of tribofilms from fully formulated oils Part 1—Films on 52100 steel. Tribol Mater Surf Interfaces 1: 48–61 (2007)
Tsai H M, Asokan K, Pao C W, Chiou J W, Du C H, Pong W F, Tsai M H, Jang L Y. Anisotropic electronic structure in quasi-one-dimensional K0.3 Mo O3: An angle-dependent x-ray absorption study. Appl Phys Lett 91: 138–141 (2007)
Morina A, Zhao H, Mosselmans J F W. In-situ reflection-XANES study of ZDDP and MoDTC lubricant films formed on steel and diamond like carbon (DLC) surfaces. Appl Surf Sci 297: 167–175 (2014)
Nash W M, Smythe D J, Wood B J. Compositional and temperature effects on sulfur speciation and solubility in silicate melts. Earth Planet Sci Lett 507: 187–198 (2019)
Lee C, Yan H, Brus L E, Heinz T F, Hone J, Ryu S. Anomalous lattice vibrations of single- and few-layer MoS2. ACS Nano 4: 2695–2700 (2010)
Peeters S, Charrin C, Duron I, Loehlé S, Thiebaut B, Righi M C. Importance of the catalytic effect of the substrate in the functionality of lubricant additives: the case of molybdenum dithiocarbamates. Mater Today Chem 21: 100487 (2021)
Pan S, Saso T, Yu N, Sokoluk M, Yao G, Umehara N, Li X. New study on tribological performance of AA7075-TiB2 nanocomposites. Tribol Int 152: 106565 (2020)
Zhang Z, Li Z, Pan S, Chai X. Enhanced strength and high-temperature wear resistance of Ti6Al4V alloy fabricated by laser solid forming. J Manuf Sci Eng 144: 111011 (2022)
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