1 Kotia, A., "Wear and performance analysis of a 4-stroke diesel engine employing nanolubricants" 37 : 54-63, 2018
2 Ratoi, M., "WS2 nanoparticles—Potential replacement for ZDDP and friction modifi er additives" 4 (4): 21238-, 2014
3 Aldana, P. U., "WS2 nanoparticles anti-wear and friction reducing properties on rough surfaces in the presence of ZDDP additive" 102 : 213-221, 2016
4 Halelfadl, S., "Viscosity of carbon nanotubes water-based nanofl uids : Infl uence of concentration and temperature" 71 : 111-117, 2013
5 Silambarasan, M., "Viscosity and thermal conductivity of dispersions of sub-micron TiO 2 particles in water prepared by stirred bead milling and ultrasonication" 55 (55): 7991-8002, 2012
6 Kedzierski, M. A., "Viscosity and density of aluminum oxide nanolubricant" 36 (36): 1333-1340, 2013
7 Kogovšek, J., "Various MoS2-, WS2-and C-based micro-and nanoparticles in boundary lubrication" 53 (53): 585-597, 2014
8 Chang, H., "Tribological property of TiO 2 nanolubricant on piston and cylinder surfaces" 495 (495): 481-484, 2010
9 Jiang, Z., "Tribological properties of oleylamine-modifi ed ultrathin WS 2 nanosheets as the additive in polyalpha olefi n over a wide temperature range" 61 (61): 24-, 2016
10 Hu, K. H., "Tribological properties of molybdenum disulfi de nanosheets by monolayer restacking process as additive in liquid paraffi n" 42 (42): 33-39, 2009
11 Khalil, W., "Tribological properties of dispersed carbon nanotubes in lubricant" 24 (24): 479-485, 2016
12 Luo, T., "Tribological properties of Al 2 O 3 nanoparticles as lubricating oil additives" 40 (40): 7143-7149, 2014
13 Bao, Y. Y., "Tribological properties and lubricating mechanism of SiO 2 nanoparticles in waterbased fluid" 182 : 12025-, 2017
14 Ghaednia, H., "Tribological performance of silver nanoparticle—Enhanced polyethylene glycol lubricants" 59 (59): 585-592, 2016
15 Gulzar, M., "Tribological performance of nanoparticles as lubricating oil additives" 18 (18): 1-25, 2016
16 Nallasamy, P., "Tribological investigations on MoS 2—Based nanolubricant for machine tool slideways" 229 (229): 559-567, 2015
17 Boshui, C., "Tribological characteristics of monodispersed cerium borate nanospheres in biodegradable rapeseed oil lubricant" 353 : 326-332, 2015
18 Talib, N., "Tribological behaviour of modifi ed jatropha oil by mixing hexagonal boron nitride nanoparticles as a bio-based lubricant for machining processes" 147 : 360-378, 2017
19 Wan, Q., "Tribological behaviour of a lubricant oil containing boron nitride nanoparticles" 102 : 1038-1045, 2015
20 Alves, S. M., "Tribological behavior of vegetable oil-based lubricants with nanoparticles of oxides in boundary lubrication conditions" 65 : 28-36, 2013
21 Chou, R., "Tribological behavior of polyalphaolefi n with the addition of nickel nanoparticles" 43 (43): 2327-2332, 2010
22 Ingole, S., "Tribological behavior of nano TiO 2as an additive in base oil" 301 (301): 776-785, 2013
23 Y. Choi, "Tribological behavior of copper nanoparticles as additives in oil" 한국물리학회 9 (9): 124-127, 2009
24 Zhang, M., "Tribological behavior of LaF3 nanoparticles as additives in poly-alpha-olefin" 65 (65): 226-235, 2013
25 Thottackkad, M. V., "Tribological analysis of surfactant modifi ed nanolubricants containing CeO2 nanoparticles" 8 (8): 125-130, 2014
26 Bon-Cheol Ku, "Tribological Effects of Fullerene (C60) Nanoparticles Added in Mineral Lubricants According to its Viscosity" 한국정밀공학회 11 (11): 607-611, 2010
27 Padgurskas, J., "Tribologic behaviour and suspension stability of iron and copper nanoparticles in rapeseed and mineral oils" 3 (3): 97-102, 2009
28 Gupta, M. K., "Tribo-investigations on oils with dispersants and hexagonal boron nitride particles" 140 (140): 31801-, 2017
29 Cremaschi, L., "Thermodynamic PROPERTIES of Al 2 O 3 nanolubricants : Part 1—Eff ects on the two-phase pressure drop" 21 (21): 607-620, 2015
30 Zhao, C., "The tribological properties of zinc borate ultrafi ne powder as a lubricant additive in sunfl ower oil" 57 (57): 425-434, 2014
31 Peng, D., "The tribological behavior of modifi ed diamond nanoparticles in liquid paraffi n" 61 (61): 213-219, 2009
32 Zin, V., "The synthesis and eff ect of copper nanoparticles on the tribological properties of lubricant oils" 12 (12): 751-759, 2013
33 Behrooz Zareh-Desari, "The Effect of Nanoparticle Additives on Lubrication Performance in Deep Drawing Process: Evaluation of Forming Load, Friction Coefficient and Surface Quality" 한국정밀공학회 16 (16): 929-936, 2015
34 Jiang, H., "Temperature dependence of the stability and thermal conductivity of an oil-based nanofl uid" 579 : 27-30, 2014
35 Chen, T., "Synthesis, characterization, and tribological behavior of oleic acid capped graphene oxide" 2014 (2014): 1-8, 2014
36 Jia, Z., "Synthesis, characterization and tribological properties of Cu/reduced graphene oxide composites" 88 : 17-24, 2015
37 Meng, Y., "Synthesis of nano-Cu/graphene oxide composites by supercritical CO 2 —Assisted deposition as a novel material for reducing friction and wear" 281 : 11-19, 2015
38 Song, X., "Synthesis of monodispersed ZnAl2O4 nanoparticles and their tribology properties as lubricant additives" 47 (47): 4305-4310, 2012
39 Zhang, L., "Synthesis and tribological properties of stearic acid-modifi ed anatase(TiO2)nanoparticles" 41 (41): 409-416, 2011
40 Agarwal, D. K., "Synthesis and characterization of kerosene–alumina nanofl uids" 60 (60): 275-284, 2013
41 Asadauskas, S. J., "Surfactants in tribology" Taylor and Francis Group 151-182, 2015
42 Sánchez-López, J. C., "Surface-modifi ed Pd and Au nanoparticles for anti-wear applications" 44 : 720-726, 2011
43 Azman, S. S. N., "Study of tribological properties of lubricating oil blend added with graphene nanoplatelets" 31 (31): 1932-1938, 2016
44 Trajano, M. F., "Study of oxide nanoparticles as additives for vegetable lubricants" 17 (17): 1124-1128, 2014
45 Sathyaseelan, B., "Structural, optical and morphological properties of post-growth calcined TiO 2 nanopowder For opto-electronic device application : Ex-situ studies" 671 : 486-492, 2016
46 Mestrom, L., "Stable ferrofl uids of magnetite nanoparticles in hydrophobic ionic liquids" 26 (26): 285602-, 2015
47 Ilyas, S. U., "Stability and thermal analysis of MWCNT-thermal oil-based nanofl uids" 527 : 11-22, 2017
48 Peng, D. X., "Size eff ects of SiO2 nanoparticles as oil additives on tribology of lubricant" 62 (62): 111-120, 2010
49 Haghighi, E. B., "Shelf stability of nanofl uids and its eff ect on thermal conductivity and viscosity" 24 (24): 105301-, 2013
50 Chu, H. Y., "Scuffing mechanism during oil-lubricated block-on-ring test with diamond nanoparticles as oil additive" 268 (268): 1423-1433, 2010
51 Dai, W., "Roles of nanoparticles in oil lubrication" 102 : 88-98, 2016
52 Wan, Q., "Rheological and tribological behaviour of lubricating oils containing platelet MoS2 nanoparticles" 16 (16): 2386-, 2014
53 Ali, M. K. A., "Reducing frictional power losses and improving the scuffi ng resistance in automotive engines using hybrid nanomaterials as nano-lubricant additives" 365 : 270-281, 2016
54 Choi, S., "Recent advances in fl exible and stretchable bio-electronic devices integrated with nanomaterials" 28 (28): 4203-4218, 2016
55 Yaogang Wang, "Processing Characteristics of Vegetable Oil-based Nanofluid MQL for Grinding Different Workpiece Materials" 한국정밀공학회 5 (5): 327-339, 2018
56 Zhu, H., "Preparation, characterization, viscosity and thermal conductivity of CaCO 3aqueous nanofluids" 53 (53): 360-368, 2010
57 Li, D., "Preparation of well-dispersed silver nanoparticles for oil-based nanofluids" 49 : 1697-1702, 2010
58 Chen, Y., "Preparation of nickel-based nanolubricants via a facile in situ one-step route and investigation of their tribological properties" 51 : 73-83, 2013
59 Li, Z., "Preparation of lanthanum trifl uoride nanoparticles surface-capped by tributyl phosphate and evaluation of their tribological properties as lubricant additive in liquid paraffin" 292 : 971-977, 2014
60 Choi, C., "Preparation method of lubricating oil and lubricating oil produced thereby"
61 Yu, L., "Preparation and tribological properties of surface-modifi ed nano-Y 2 O 3 as additive in liquid paraffin" 263 : 655-659, 2012
62 Clary, D. R., "Preparation and thermal properties of CuO particles" 115 (115): 1767-1775, 2011
63 Yang, L., "Preparation and stability of Al 2 O 3 nano-particle suspension of ammonia–water solution" 31 (31): 3643-3647, 2011
64 C. Choi, "Preparation and heat transfer properties of nanoparticle-in-transformer oil dispersions as advanced energy-efficient coolants" 한국물리학회 8 (8): 710-712, 2008
65 Xiong, X., "Preparation and evaluation of tribological properties of cu nanoparticles surface modifi ed by tetradecyl hydroxamic acid" 46 : 211-220, 2012
66 Sharma, S. K., "Preparation and evaluation of stable nanofl uids for heat transfer application : a review" 79 : 202-212, 2016
67 Zhang, M., "Performance and anti-wear mechanism of Cu nanoparticles as lubricating oil additives" 61 (61): 311-318, 2009
68 Sharif, M. Z., "Performance analysis of SiO2/PAG nanolubricant in automotive air conditioning system" 75 : 204-216, 2017
69 Dubey, M. K., "PTFE based nano-lubricants" 306 (306): 80-88, 2013
70 Xing, M. B., "Nanorefrigeration oil formed by C60, CNTs and mineral oil for air conditioner" 629 : 247-254, 2013
71 Alves, S. M., "Nanolubricants developed from tiny CuO nanoparticles" 100 : 263-271, 2016
72 Timofeeva, E. V., "Nanofl uids for heat transfer : An engineering approach" 6 (6): 182-, 2011
73 Ivanov, M., "Nanodiamond-based nanolubricants for motor oils" 21 (21): 17-24, 2017
74 Taha-Tijerina, J., "Multifunctional Nanofl uids with 2D nanosheets for thermal and tribological management" 302 (302): 1241-1248, 2013
75 Rahmati, B., "Morphology of surface generated by end milling AL6061-T6 using molybdenum disulfi de(Mos2)nanolubrication in end milling machining" 66 : 685-691, 2014
76 Sia, S. Y., "Morphology investigation of worn bearing surfaces using SiO 2 nanolubrication system" 70 : 1063-1071, 2014
77 Mosleh, M., "Modifi cation of sheet metal forming fl uids with dispersed nanoparticles for improved lubrication" 267 (267): 1220-1225, 2009
78 Alazemi, A. A., "MoS2 nanolayer coated carbon spheres as an oil additive for enhanced tribological performance" 110 : 367-377, 2016
79 Ali, M. K. A., "Minimizing of the boundary friction coeffi-cient in automotive engines using Al 2 O 3 and TiO 2 nanoparticles" 18 (18): 377-, 2016
80 Kalin, M., "Mechanisms and improvements in the friction and wear behavior using MoS2 nanotubes as potential oil additives" 280 : 36-45, 2012
81 Guo, D., "Mechanical properties of nanoparticles: basics and applications" 47 : 1-25, 2014
82 Afi fah, A. N., "Magnetoviscous eff ect and thermomagnetic convection of magnetic fl uid : A review" 55 : 1030-1040, 2016
83 Xie, H., "Lubrication performance of MoS2 and SiO 2 nanoparticles as lubricant additives in magnesium alloy-steel contacts" 93 : 63-70, 2016
84 Zheng, Z. Q., "Lightcontrolling, fl exible and transparent ethanol gas sensor based on ZnO nanoparticles for wearable devices" 5 : 11070-, 2015
85 Azman, N. F., "Investigation of tribological properties of CuO/palm oil nanolubricant using pin-on-disc tribotester" 6 : 30-37, 2018
86 Zheng, D., "Investigation of the tribology behaviour of the graphene nanosheets as oil additives on textured alloy cast iron surface" 387 : 66-75, 2016
87 Vakili-Nezhaad, G. R., "Investigation of the eff ect of multiwalled carbon nanotubes on the viscosity index of lube oil cuts" 196 : 997-1007, 2009
88 Choi, Y., "Investigation of anti-wear and extreme pressure properties of nano-lubricant using graphite and Ag nanoparticles" 11 (11): 560-565, 2011
89 Wang, X. J., "Infl uence of pH and SDBS on the stability and thermal conductivity of nanofl uids" 23 (23): 2684-2689, 2009
90 Wang, A., "In situ synthesis of copper nanoparticles within ionic liquid-in-vegetable oil microemulsions and their direct use as high effi cient nanolubricants" 4 : 45251-45257, 2014
91 Lahouij, I., "In situ TEM observation of the behavior of an individual fullerene-like MoS2 nanoparticle in a dynamic contact" 42 (42): 133-140, 2011
92 Ali, M. K. A., "Improving the tribological characteristics of piston ring assembly in automotive engines using Al 2 O 3and TiO 2 nanomaterials as nano-lubricant additives" 103 : 540-554, 2016
93 Gulzar, M., "Improving the AW/EP ability of chemically modifi ed palm oil by adding CuO and MoS2nanoparticles" 88 : 271-279, 2015
94 Zin, V., "Improved tribological and thermal properties of lubricants by graphene based nano-additives" 6 (6): 59477-59486, 2016
95 Rasheed, A. K., "Heat transfer and tribological performance of graphene nanolubricant in an internal combustion engine" 103 : 504-515, 2016
96 Rasheed, A. K., "Graphene based nanofl uids and nanolubricants—Review of recent developments" 63 : 346-362, 2016
97 Zhou, J., "Functionalized gold nanoparticles : Synthesis, structure and colloid stability" 331 (331): 251-262, 2009
98 Sgroi, M., "Friction reduction benefi ts in valvetrain system using IF-MoS2 added engine oil" 58 (58): 207-214, 2015
99 Spikes, H., "Friction modifi er additives" 60 (60): 1-26, 2015
100 Rivera-Solorio, C. I., "Formulation techniques for nanofluids" 7 (7): 208-215, 2013
101 Thottackkad, V. M., "Experimental studies on the tribological behaviour of engine oil(SAE15W40)with the addition of CuO nanoparticles" 66 (66): 289-297, 2014
102 Kamalgharibi, M., "Experimental studies on the stability of CuO nanoparticles dispersed in diff erent base fl uids : Infl uence of stirring, sonication and surface active agents" 52 (52): 55-62, 2016
103 Fedele, L., "Experimental stability analysis of diff erent water-based nanofl uids" 6 (6): 300-, 2011
104 Lou, J. F., "Experimental investigation of graphite nanolubricant used in a domestic refrigerator" 7 (7): 1-9, 2015
105 Fontes, D. H., "Experimental evaluation of thermal conductivity, viscosity and breakdown voltage AC of nanofl uids of carbon nanotubes and diamond in transformer oil" 58 : 115-121, 2015
106 Ettefaghi, E., "Experimental evaluation of engine oil properties containing copper oxide nanoparticles as a nanoadditive" 4 (4): 28-, 2013
107 Zhang, Y., "Experimental evaluation of MoS2 nanoparticles in Jet mql grinding with diff erent types of vegetable oil as base oil" 87 : 930-940, 2015
108 Kotia, A., "Experimental analysis for rheological properties of aluminium oxide(Al 2 O 3)/gear oil(SAE EP-90)nanolubricant used in HEMM" 67 (67): 600-605, 2015
109 Manu Varghese Thottackkad, "Experimental Evaluation on the Tribological Properties of Coconut Oil by the Addition of CuO Nanoparticles" 한국정밀공학회 13 (13): 111-116, 2012
110 Koshy, C. P., "Evaluation of the tribological and thermo-physical properties of coconut oil added with MoS2 nanoparticles at elevated temperatures" 330 : 288-308, 2015
111 Lee, G. J., "Enhanced thermal conductivity of nanofl uids containing graphene nanoplatelets prepared by ultrasound irradiation" 49 (49): 1506-1511, 2014
112 López, T. D. F., "Engineered silica nanoparticles as additives in lubricant oils" 16 (16): 1-11, 2015
113 Yujin Hwang, "Effect of the size and morphology of particles dispersed in nano-oil on friction performance between rotating discs" 대한기계학회 25 (25): 2853-2857, 2011
114 Çelik, O. N., "Effect of nano hexagonal boron nitride lubricant additives on the friction and wear properties of AISI 4140 Steel" 31 (31): 501-506, 2013
115 Bhaumik, S., "Effect of nano and micro friction modifier based lubricants on wear behavior between steel–steel contacts" 39 (39): 136-143, 2017
116 Wamkam, C. T., "Eff ects of pH on heat transfer nanofl uids containing ZrO 2 and TiO= nanoparticles" 109 (109): 024305-, 2011
117 Kim, J. H., "Eff ect of surfactant on tribological performance and tribochemistry of boric acid based colloidal lubricants" 6 (6): 134-141, 2012
118 Maheswaran, R., "Eff ect of nano sized garnet particles dispersion on the viscous behavior of extreme pressure lubricant oil" 223 : 643-651, 2016
119 Abdullah, M. I. H. C., "Eff ect of hexagonal boron nitride nanoparticles as an additive on the extreme pressure properties of engine oil" 68 (68): 441-445, 2016
120 Kole, M., "Eff ect of aggregation on the viscosity of copper oxide-gear oil nanofl uids" 50 (50): 1741-1747, 2011
121 Yu, F., "Dispersion stability of thermal nanofl uids" 27 (27): 531-542, 2017
122 Gulzar, M., "Dispersion stability and tribological characteristics of TiO 2 /SiO 2 nanocomposite-enriched biobased lubricant" 60 (60): 670-680, 2017
123 Ramon-Raygoza, E. D., "Development of nanolubricant based on impregnated multilayer graphene for automotive applications : Analysis of tribological properties" 302 : 363-371, 2016
124 Sia, S. Y., "Development of SiO 2 nanolubrication system to be used in sliding bearings" 71 (71): 1277-1284, 2014
125 Jama, M., "Critical review on nanofl uids : preparation, characterization, and applications" 2016 : 1-22, 2016
126 Wu, D., "Critical issues in nanofl uids preparation, characterization and thermal conductivity" 5 (5): 103-112, 2009
127 Vijaykumar S. Jatti, "Copper oxide nano-particles as friction-reduction and anti-wear additives in lubricating oil" 대한기계학회 29 (29): 793-798, 2015
128 Yin, J., "Conductivity and polarization of carbonaceous nanotubes derived from polyaniline nanotubes and their electrorheology when dispersed in silicone oil" 48 (48): 2958-2967, 2010
129 Jendrzej, S., "Colloidal stability of metal nanoparticles in engine oil under thermal and mechanical load" 40 (40): 1569-1576, 2017
130 Reddy, K. R., "Carbon functionalized TiO 2 nanofi bers for high effi ciency photocatalysis" 1 (1): 15012-, 2014
131 Anushree, C., "Assessment of long term stability of aqueous nanofl uids using diff erent experimental techniques" 222 : 350-358, 2016
132 Zareh-Desari, B., "Assessing the lubrication performance of vegetable oil-based nano-lubricants for environmentally conscious metal forming processes" 135 : 1198-1209, 2016
133 Lee, J., "Application of fullerene-added nano-oil for lubrication enhancement in friction surfaces" 42 (42): 440-447, 2009
134 Sabareesh, R. K., "Application of TiO2 nanoparticles as a lubricant-additive for vapor compression refrigeration systems–An experimental investigation" 35 (35): 1989-1996, 2012
135 Srinivas, V., "Antiwear, antifriction, and extreme pressure properties of motor bike engine oil dispersed with molybdenum disulfi de nanoparticles" 60 (60): 12-19, 2017
136 Peña-Parás, L., "Antiwear and extreme pressure properties of nanofl uids for industrial applications" 57 (57): 1072-1076, 2014
137 Gupta, R. N., "Antiwear and extreme pressure performance of castor oil with nano-additives" 0 : 1-13, 2017
138 Ma, S., "Anti-wear and friction performance of ZrO2 nanoparticles as lubricant additive" 8 (8): 468-472, 2010
139 이주현, "Analysis of Oxide (Al2O3, CuO, and ZnO) and CNT Nanoparticles Disaggregation Effect on the Thermal Conductivity and the Viscosity of Nanofluids" 한국정밀공학회 15 (15): 703-710, 2014
140 Zhao, J., "An investigation on the tribological properties of multilayer graphene and Mos2 nanosheets as additives used in hydraulic applications" 97 : 14-20, 2016
141 Sadri, R., "An experimental study on thermal conductivity and viscosity of nanofl uids containing carbon nanotubes" 9 (9): 151-, 2014
142 Zeng, Z., "A study n wear and worn surfaces of grey cast iron aff ected by a novel silicate additive" 27 (27): 479-487, 2015
143 Devendiran, D. K., "A review on preparation, characterization, properties and applications of nanofl uids" 60 : 21-40, 2016
144 Yu, W., "A review on nanofl uids : preparation, stability mechanisms, and applications" 2012 : 1-17, 2012
145 Ghadimi, A., "A review of nanofl uid stability properties and characterization in stationary conditions" 54 (54): 4051-4068, 2011
146 Sadeghinezhad, E., "A comprehensive review on graphene nanofl uids : recent research, development and applications" 111 : 466-487, 2016
147 Chang-Gun Lee, "A Study on The Tribological Characteristics of Graphite Nano Lubricants" 한국정밀공학회 10 (10): 85-90, 2009