SYNERGISTIC TRIBOLOGICAL PROPERTIES OF SYNTHETIC MAGNESIUM SILICATE HYDROXIDE COMBINED WITH AMPHIPHILIC MOLECULES
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Gershman, I., Gershman, E.I., Mironov, A.E., Fox-Rabinovich, G.S., Veldhuis, S.C.,2016, Application of the self-organization phenomenon in the development of wear resistant materials-A review, Entropy, 18(11), 385.
Lee, K., Hsu, J., Naugle, D., Liang, H., 2016, Multi-phase quasicrystalline alloys for superior wear resistance, Mater Des, 108, pp. 440–7.
Bhushan, B., Gupta, B.K., 1991, Handbook of Tribology: Materials, coatings, and surface treatments, McGraw-Hill, New York, United States.
Ali, M.K.A., Xianjun, H., 2015, Improving the tribological behavior of internal combustion engines via the addition of nanoparticles to engine oils, Nanotechnol Rev, 4, pp. 347–58.
Gulzar, M., Masjuki, H.H., Kalam, M.A., Varman, M., Zulkifli, N.W.M., Mufti, R.A., et al, 2016, Tribological performance of nanoparticles as lubricating oil additives, J Nanoparticle Res, 18, pp. 1–25.
Dai, W., Kheireddin, B., Gao, H., Liang, H., 2016, Roles of nanoparticles in oil lubrication, Tribol Int, 102, pp. 88–98.
Rokosz, M.J., Chen, A.E., Lowe-Ma, C.K., Kucherov, A.V., Benson, D., Paputa Peck, M.C., et al., 2001, Characterization of phosphorus-poisoned automotive exhaust catalysts, Appl Catal B Environ, 33, pp. 205–15.
Mookherjee, M., Stixrude, L., 2009, Structure and elasticity of serpentine at high-pressure, Earth Planet Sci Lett, 279, pp. 11–9.
Veblen, D.R., Buseck, P.R., 1979, Serpentine minerals: intergrowths and new combination structures, Science, 206, pp. 1398-400.
Sclar, C.B., Carrison, L.C., Thomas, P., et al., 1966, High-pressure reaction and shear strength of serpentinized dunite, Science; 153, pp. 1285-7.
Riecker, R.E., Rooney, T.P., 1966, Weakening of dunite by serpentine dehydration, Science, 152, pp. 196-8.
Stalder, R., Ulmer, P., 2001, Phase relations of a serpentine composition between 5 and 14 GPa: Significance of clinohumite and phase E as water carriers into the transition zone, Contrib to Mineral Petrol, 140, pp. 670–9.
Yu, H.L., Xu, Y., Shi, P.J., Wang, H.M., Zhao, Y., Xu, B.S., et al., 2010, Tribological behaviors of surface-coated serpentine ultrafine powders as lubricant additive, Tribol Int, 43, pp. 667–75.
Yu, H., Xu, Y., Shi, P., Wang, H., Wei, M., Zhao, K., et al., 2013, Microstructure, mechanical properties and tribological behavior of tribofilm generated from natural serpentine mineral powders as lubricant additive, Wear, 297, pp. 802–10.
Zhang, B., Xu, Y., Gao, F., Shi, P., Xu, B., Wu, Y., 2011, Sliding friction and wear behaviors of surface-coated natural serpentine mineral powders as lubricant additive, Appl Surf Sci, 257, pp. 2540–9.
Chang, Q., Rudenko, P., Miller, D.J., Wen, J., Berman, D., 2017, Tribology International Operando formation of an ultra-low friction boundary fi lm from synthetic magnesium silicon hydroxide additive, Tribiology Int, 110, pp. 35–40.
Wang, B., Chang, Q.Y., Gao, K., Fang, H.R., Qing, T., Zhou, N.N., 2018, The synthesis of magnesium silicate hydroxide with different morphologies and the comparison of their tribological properties, Tribol Int, 119, pp. 672–9.
Gao, K., Chang, Q., Wang, B., Zhou, N., Qing, T., 2018, The tribological performances of modified magnesium silicate hydroxide as lubricant additive, Tribol Int, 121, pp. 64–70.
Gulzar, M., Masjuki, H., Varman, M., Kalam, M., Mufti, R.A., Zulkifli, N., et al., 2015, Improving the AW/EP ability of chemically modified palm oil by adding CuO and MoS nanoparticles, Tribol Int, 88, pp. 271–9.
Chen, S., Liu, W., 2006, Oleic acid capped PbS nanoparticles: Synthesis, characterization and tribological properties, Mater Chem Phys, 98, pp. 183–9.
Song, X., Zheng, S., Zhang, J., Li, W., Chen, Q., Cao, B., 2012, Synthesis of monodispersed ZnAl2O4 nanoparticles and their tribology properties as lubricant additives, Mater Res Bull, 47, pp. 4305–10.
Hugh, S., 2015, Friction modifier additives, Tribology Letters, 60, pp. 1-31.
Campen, S., Green, J.H., Lamb, G.D., Spikes, H.A., 2015, In Situ Study of Model Organic Friction Modifiers Using Liquid Cell AFM; Saturated and Mono-unsaturated Carboxylic Acids, Tribol Lett, 57, pp. 1–32.
Bhushan, B., Liu, H., 2004, Self-assembled monolayers for controlling adhesion, friction and wear, in Bushan, B. (Ed.), Nanotribology and Nanomechanics, Springer, Berlin, Heidelberg, pp. 885-928.
Ta, D.T., Tieu, A.K., Zhu, H.T., Kosasih, B., 2015, Thin film lubrication of hexadecane confined by iron and iron oxide surfaces: A crucial role of surface structure, J Chem Phys, 143, 164702.
Loehle, S., Matta, C., Minfray, C., Mogne, T., Le Martin, J.M., Iovine, R., et al., 2014, Mixed lubrication with C18 fatty acids: Effect of unsaturation, Tribol Lett, 53, pp. 319–28.
Loehlé, S., Matta, C., Minfray, C., Mogne, T. Le, Iovine, R., Obara, Y., et al., 2015, Mixed lubrication of steel by C18 fatty acids revisited. Part I: Toward the formation of carboxylate, Tribol Int, 82, pp. 218–27.
Ewen, J.P., Echeverri Restrepo, S., Morgan, N., Dini, D., 2017, Nonequilibrium molecular dynamics simulations of stearic acid adsorbed on iron surfaces with nanoscale roughness. Tribol Int,107, pp. 264–73.
Doig, M., Warrens, C.P., Camp, P.J., 2014, Structure and friction of stearic acid and oleic acid films adsorbed on iron oxide surfaces in squalane, Langmuir, 30, pp. 186–95.
DOI: https://doi.org/10.22190/FUME190120009W
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