Title of Invention	NANOPARTICLE COMPOSITIONS AND METHODS FOR MAKING AND USING THE SAME
Abstract	A composition that includes solid lubricant nanoparticles and an organic medium is disclosed. Also disclosed are nanoparticles that include layered materials. A method of producing a nanoparticle by milling layered materials is provided. Also disclosed is a method of making a lubricant, the method including milling layered materials to form nanoparticles and incorporating the nanoparticles into a base to form a lubricant.

Title of Invention

NANOPARTICLE COMPOSITIONS AND METHODS FOR MAKING AND USING THE SAME

Abstract

A composition that includes solid lubricant nanoparticles and an organic medium is disclosed. Also disclosed are nanoparticles that include layered materials. A method of producing a nanoparticle by milling layered materials is provided. Also disclosed is a method of making a lubricant, the method including milling layered materials to form nanoparticles and incorporating the nanoparticles into a base to form a lubricant.

Full Text	NANOPARTICLE COMPOSITIONS AND METHODS FOR MAKING AND USING THE SAME CROSS-REFERENCE TO RELATED APPLICATIONS [0001 ] This application claims priority to United States Provisional Application No. 60/758,307 filed on January 12,2006, which is hereby fully incorporated by reference. STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT [0002] Efforts associated with the subject matter of this application were supported in part by a grant from the National Science Foundation (NSF/DMI0115532). The government may have certain rights in any patent issuing from this application. BACKGROUND [0003} Over the years, considerable effort has been expended to develop nanostructures that can be used as lubricants, coatings, or delivery mechanisms. New ways to improve nanoparticle compositions, their method of manufacture, and their use are sought SUMMARY [0004] In one aspect, a composition is described, comprising solid lubricant nanoparticles and an organic medium. [0005] In another aspect, nanoparticles comprising a layered material are disclosed. [0006] In a further aspect, a method of producing a nanoparticle comprising milling layered materials is provided. [0007] In yet another aspect, a method of making a lubricant is disclosed, in which the. method comprises milling layered materials to form nanoparticles and incorporating the nanoparticles into a base to form a lubricant. [0008] Other aspects will become apparent by consideration of the detailed description and accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS [0009] Figure 1 is a diagram illustrating a method of producing solid lubricant nanoparticles. [0010] Figure 2 is a diagram illustrating one method of preparing nanoparticle based lubricants. [0011] Figure 3 shows transmission electron microscopy (TEM) micrographs of molybdenum disulpbide particles. Figure 3(A) shows molybdenum disulphide as it is available, typically from about a few microns to submicron size. Figure 3(B) shows molybdenum disulphide that has been ball milled in air for 48 hours. Figure 3(C) is a high resolution electron microscopy image that shows molybdenum disulphide that has been ball milled in air for 48 hours. Figure 3(D) is a high-resolution transmission electron microscopy (HRTEM) image that shows molybdenum disulphide that has been ball milled in air for 48 hours followed by ball milling in oil for 48 hours, [0012] Figure 4 is a graph showing XRD spectra of molybdenum disulphide particles. Figure 4(A) is the XRD spectra for molybdenum disulphide that has been ball milled in air for 48 hours followed by ball milling in oil for 48 hours. Figure 4(B) is the XRD spectra for molybdenum disulphide that has been ball milled in air for 48 hows Figure 4(C) is the XRD spectra for molybdenum disulphide that has not been ball milled. [0013] Figure 5 is a graph showing XPS spectra of molybdenum, disulphide particles. The carbon peak for molybdenum disulphide that has not been ball milled is shown, as well as the carbon peak for molybdenum disulpbide that has been ball milled in air for 48 hours, followed by ball millmg in oil for 48 hours. [0014] Figure 6 shows graphs and bar charts depicting tribological test data for different additives in paraffin oil. Figure 6(A) shows the average wear scar diameter for a base oil (paraffin oil), paraffin oil with micron sized M0S2, paraffin oil with M0S2 that was milled in air for 48 hours, and paraffin oil with M0S2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours. Figure 6(B) shows the load wear index for paraffin oil without a nanoparticle additive, paraffin oil with micron sized M0S2, paraffin oil with M0S2 that was milled in air for 48 hours, and paraffin oil with M0S2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours. Figure 6(C) shows the COF for paraffin oil without a nanoparticle additive, paraffin oil with micron sized M0S2 (c-MoS2), paraffin oil with M0S2 that was milled in air for 48 hours (d-MoS2), and paraffin oil with M0S2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours (n- M0S2). Figure 6(D) shows the extreme pressure data for paraffin oil with micron sized M0S2 (C-M0S2), paraffin oil with M0S2 that was milled in air for 48 hours (d-MoS2), and paraffin oil with M0S2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours (n-MoS2). In each test the solid lubricant nanoparticle additive was present in the amount of 1% by weight. [0015); Figure 7 is a TEM image showing the architecture of molybdenum disulphide nanoparticles (15-70 nm average size). Figure 7(A) shows the close caged dense oval shaped architecture of molybdenum disulphide nanoparticles that have been ball milled in air for 48 hours. Figure 7(B) shows the open ended oval shaped architecture of molybdenum disulphide nanoparticles that have been ball milled in air for 48 hours followed by ball milling in canola oil for 48 hours. [00161 Figure 8 is a graph depicting a comparison of wear scar diameters for different additives in paraffin oil. One additive is crystalline molybdenum disulphide (C-M0S2)- Another is molybdenum disulphide nanoparticles that were ball milled in air (n- MoS2). Another additive is molybdenum disulphide nanoparticles that were ball milled in air followed by ball milling in canola oil and to which, a phospholipid emulsifier was added (n- M0S2 + Emulsifier). [00171 Figure 9 shows photographs and graphs produced using energy dispersive x-ray analysis (EDS) depicting the chemical analysis of wear scar diameters in four-ball tribological testing for nanoparticle based lubricants. Figure 9(A) shows paraffin oil without any nanoparticle composition additive. Figure 9(B) shows paraffin oil with molybdenum disulphide nanoparticles that have been ball milled in air for 48 hours; followed by ball milling in oil for 48 hours and treated with a phospholipid emulsifier. DETAILED DESCRIPTION [0018] Before any embodiments are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. [0019] Any numerical range recited herein includes all values from the lower value to the upper value. For example, if a concentration range is stated as 1% to 50%, it is intended that values such as 2% to 40%, 10% to 30%, or 1% to 3%, etc., are expressly enumerated in this specification. These are only examples of what is specifically intended, and all possible combinations of numerical values between and including the lowest value and the highest value enumerated are to be considered to be expressly stated in this application. [0020] Herein described are compositions and methods for making compositions comprising solid lubricant nanoparticles and an organic medium. Also described are nanoparticles comprising layered materials. The nanoparticles may be solid lubricant nanoparticles. The nanoparticles may be made from starting materials or solid lubricant starting materials. Examples of solid lubricants may include, but are not limited to, layered materials, suitably chalcogenides, more suitably, molybdenum disulphide, tungsten disulphide, or a combination thereof. Another suitable layered material is graphite or intercalated graphite. Other solid lubricants that may be used alone or in combination with the layered materials are polytetrafluoroethylene (Teflon®), boron nitride (suitably hexagonal boron nitride), soft metals (such as silver, lead, nickel, copper), cerium fluoride, zinc oxide, silver sulfate, cadmium iodide, lead iodide, barium fluoride, tin sulfide, zinc phosphate, zinc sulfide, mica, boron nitrate, borax, fluorinated carbon, zinc phosphide:, boron, or a combination thereof. Fluorinated carbons may be, without limitation, carbon-based materials such as graphite which has been fluorinated to improve its aesthetic characteristics. Such materials may include, for example, a material such as CF.sub.x wherein x ranges from about 0.05 to about 1.2. Such a material is produced by Allied Chemical under the trade name Accufluor. [00211 The methods may include milling a solid lubricant feed. In one embodiment, the solid lubricant feed may be capable of being milled to particles comprising an average dimension of about 500 nanometers (submicron size) to about 10 nanometers. Suitably, the particles may have an average particle dimension of less than or equal to about 500 nanometers, suitably less than or equal to about 100 nanometers, suitably less than or equal to about 80 nanometers, and more suitably less than or equal to about 50 nanometers. Alternatively, the ball milling may result in milled solid lubricant particles comprising a mixture, the mixture comprising particles having an average particle dimension of less than or equal to about 500 nanometers, plus larger particles. Milling may include, among other things, ball milling and chemo mechanical milling. Examples of ball milling may include dry ball milling, wet ball milling, and combinations thereof. Ball milling may refer to an impaction process that may include two interacting objects where one object may be a ball, a rod, 4 pointed pins (jack shape), or other shapes. Chemo mechanical milling may refer to an impaction process that may form a complex between an organic medium and a nanoparticle. As a result of chemo mechanical milling, the organic medium may coat, encapsulate, or intercalate the nanoparticles. [0022] In another embodiment, the solid lubricant feed may be dry milled and then wet milled. An emulsifier may be mixed with a base and added to the wet milled particles. Dry milling may refer to particles that have been milled in the presence of a vacuum, a gas, or a combination thereof. Wet milling may refer to particles that have been milled in the presence of a liquid. [0023] The solid lubricant nanoparticle composition may further comprise an organic medium. Examples of organic mediums include, but are not limited to, oil mediums, grease mediums, alcohol mediums, or combinations thereof. Specific examples of organic mediums include, but are not limited to, composite oil, canola oil, vegetable oils, soybean oil, corn oil, ethyl and methyl esters of rapeseed oil, distilled monoglycerides, monoglycerides, diglycerides, acetic acid esters of monoglycerides, organic acid esters; of monoglycerides, sorbitan, sorbitan esters of fatty acids, propylene glycol esters of fatty acids, polyglycerol esters of fatty acids, n-hexadecane, hydrocarbon oils, phospholipids, or a. combination thereof. Many of these organic media may be environmentally acceptable. [0024] The composition may contain emulsifiers, surfactants, or dispersants. Examples of emulsifiers may include, but are not limited to, emulsifiers having a hydrophilic-lipophilic balance (HLB) from about 2 to about 7; alternatively, a HLB from about 3 to about 5; or alternatively, a HLB of about 4. Other examples of emulsifiers may include, but are not limited to, lecithins, soy lecithins, phospholipids lecithins, detergents, distilled monoglycerides, monoglycerides, diglycerides, acetic acid esters of monoglycerides, organic acid esters of monoglycerides, sorbitan esters of fatty acids, propylene glycol esters of fatty acids, polyglycerol esters of fatty acids, compounds containing phosphorous, compounds containing sulfur, compounds containing nitrogen, or a combination thereof. [0025] A method of making a lubricant is described. The composition may be used as an additive dispersed in a base. Examples of bases may include, but are not limited to, oils, greases, plastics, gels, sprays, or a combination thereof. Specific examples of bases may include, but are not limited to, hydrocarbon oils, vegetable oils, com oil, peanut oil, canola oil, soybean oil, mineral oil, paraffin oils, synthetic oils, petroleum gels, petroleum greases, hydrocarbon gels, hydrocarbon greases, lithium based greases, fluoroether based greases, ethylenebistearamide, waxes, silicones, or a combination thereof. [0026] Described herein is a method of lubricating or coating an object that is part of an end application with a composition comprising at least one of solid mbricant nanoparticles and an organic medium. Further described is a method of lubricating an object by employing the composition comprising solid lubricant nanoparticles and an organic medium as a delivery mechanism. [0027] Disclosed herein are compositions and methods of preparing nanoparticle based lubricants that, among various advantages, display enhanced dispersion stability and resistance to agglomeration. Figure 1 illustrates a method of preparing nanoparticle based lubricants or compositions. A solid lubricant feed is introduced via line 210 to a ball milling processor 215. Ball milling is carried out in the processor 215 and the solid lubricant feed is milled to comprise particles having an average particle dimension of less than or equal to about 500 nanometers, suitably less than or equal to about 100 nanometers, suitably less than or equal to about 80 nanometers, and more suitably less than or equal to about 50 nanometers. Alternatively, the ball milling may result in milled solid lubricant particles comprising a mixture, the mixture comprising particles having an average particle dimension of less than or equal to about 500 nanometers, plus larger particles. The ball milling may be high energy ball milling, medium energy ball milling, or combinations thereof. Additionally, in various embodiments the ball milling may be carried out in a vacuum, in the presence of a gas, in the presence of a liquid, in the presence of a second solid, or combinations thereof. The nanoparticle composition may be removed from the processor via line 220. The nanoparticle composition may be a nanoparticle based lubricant. [0028] In alternative embodiments, the ball milling may comprise a first ball milling and at least one more subsequent ball millings, or ball milling and/or other processing as appropriate. Suitably, the ball milling may comprise dry milling followed by wet milling. Figure 2 illustrates a further method 100 of preparing nanoparticle: based lubricants where dry milling is followed by wet milling. Feed 110 introduces a solid lubricant feed into a ball milling processor 115 where dry ball milling, such as in a vacuum or in air, reduces the solid lubricant feed to particles having an average dimension of the size described above. Line 120 carries the dry milled particles to a wet milling processor 125. Via line 160 the dry milled particles are combined with a composite oil or an organic medium prior to entering the wet milling processor 125. Alternatively, the organic medium and dry milled particles may be combined in the wet milling processor 125. In further alternative embodiments (not shown), the dry milling and wet milling may be carried out in a single processor where the organic medium is supplied to the single processor for wet milling after initially carrying out dry milling. In other alternative embodiments, the balls in the ball milling apparatus may be coated with the organic medium to incorporate the organic medium in the solid lubricant nanoparticles. [0029] After wet milling, line 130 carries the wet milled particles to a container 135, which may be a sonication device. Alternatively, line 130 may carry a mixture comprising solid lubricant nanoparticles, organic medium, and a complex comprising the solid lubricant nanoparticles combined with an organic medium. [0030] In another embodiment, prior to introduction of the wet milled particles into the eontainer 135, abase may be fed to the container 135 via line 150. Alternatively, the base . may be supplied to the wet milling processor 125 and the mixing, which may include sonicating, may be carried out in the wet milling processor 125. In such embodiments the solid lubricant nanoparticle composition may be employed as an additive and dispersed in the base. A base may be paired with a solid lubricant nanoparticle composition according to the ability of the base and the solid lubricant nanoparticle composition to blend appropriately. In such cases the solid lubricant nanoparticle composition may enhance performance of the base. [0031] In a further embodiment, an emulsifier may be mixed with the base. Emulsifiers may further enhance dispersion of the solid lubricant nanoparticle composition in the base. The emulsifier may be selected to enhance the dispersion stability of a nanoparticle composition in a base. An emulsifier may also be supplied to the container 135 via line 140. In many embodiments, the emulsifier and base are combined in the container 135 prior to introduction of the wet milled particles. Prior mixing of the emulsifier with the base may enhance dispersion upon addition of complexes of solid lubricant nanoparticles and organic medium and/or solid lubricant nanoparticles by homogeneously dispersing/dissolving the complexes/nanoparticles. In some embodiments, the mixing of the emulsifier and base may comprise sonicating. Alternatively, the emulsifier may be supplied to the wet milling processor 125 and the mixing, which may include sonicating, may be carried out in the wet milling processor 125. The lubricant removed from the container 135 via line 120 may be a blend comprising the wet milled particles, organic medium, and base. The blend may further comprise an emulsifier. In other alternative embodiments, additives; may be added to the nanoparticle based lubricant during interaction with a mating surface. [00321 In a further embodiment, antioxidants or anticorrosion agents may be milled with the solid lubricant nanoparticles. Examples of antioxidants include, but are not limited to, hindered phenols, alkylated phenols, alkyl amines, aryl amines, 2,6-di-tert-butyl-4- methylphenol, 4,4'-di-tert-octyldiphenylamine, tert-Butyl hydroquinone, tris(2,4-di-tert- butylphenyl)phosphate, phosphites, thioesters, or a combination thereof. Examples of anticorrosion agents include, but are not limited to, alkaline-earth metal bisalkylphenolsulphonates, dithiophosphates, alkenylsuccinic acid half-amides, or a combination thereof. In another embodiment, biocidals may be milled with the solid lubricant nanoparticles. Examples of biocidals may include, but are not limited to, alkyl or kydroxylamine benzotriazole, an amine salt of a partial alkyl ester of an alkyl, alkenyl succinic acid, or a combination thereof. [0033] In yet another embodiment, further processing of wet milled particles may comprise removal of oils that are not a part of a complex with the solid lubricant particles. Such methods may be suitable for applications that benefit from use of dry particles of solid lubricant, such as coating applications. Oil and/or other liquids can be removed from wet milled particles to produce substantially dry solid lubricant particles and complexes. Such wet milling followed by drying may produce a solid lubricant with reduced tendency to agglomerate. In specific embodiments, an agent, such as acetone, can be added that dissolves oils that are not a part of a complex, followed by a drying process such as supercritical drying, to produce a substantially dry solid lubricant comprising particles treated by milling in an organic medium. [0034] Ball milling conditions may vary and, in particular, conditions such as temperature, milling time, and size and materials of the balls and vials may be manipulated. In various embodiments, ball milling may be carried out from about 12 hours to about 50 hours, suitably from about 36 hours to about 50 hours, suitably from about 40 hours to about 50 hours, and more suitably at about 48 hours. Suitably, ball milling is conducted at room temperature. The benefits of increasing milling time may comprise at least one of increasing the time for the organic medium and solid lubricant nanoparticles to interact; and producing finer sizes, better yield of nanoparticles, more uniform shapes, and more passive surfaces. An example of ball milling equipment suitable for carrying out the described milling includes the SPEX CertiPrep model 8000D, along with hardened stainless steel vials and hardened stainless steel grinding balls, but any type of ball milling apparatus may be used. In one embodiment, a stress of 600-650 MPa, a load of 14.9 N, and a strain of 10-3-10-4 per sec may be used. [0035] The proportions of the components in a nanoparticle based lubricant may contribute to performance of the lubricant, such as the lubricant's dispersion stability and ability to resist agglomeration. In wet milling, suitable ratios of solid lubricant nanoparticles to organic medium may be about 1 part particles to about 4 parts organic medium by weight, suitably, about 1 part particles to about 3 parts organic medium by weight, suitably, about 3 parts particles to about 8 parts organic medium by weight, suitably, about 2 parts particles to about 4 parts organic medium by weight, suitably, about 1 part particles to about 2 parts organic medium by weight, and suitably, about 1 part particles to about 1.5 parts organic medium by weight [0036] Suitable ratios of organic medium to emulsifier in a lubricant including the solid lubricant nanoparticles may be about 1 part organic medium to less than or equal to about I part emulsifier, suitably, about 1 part organic medium to about 0.5 parts emulsifier by weight, or suitably, from about 0.4 to about 1 part emulsifier for about 1 part organic medium by weight. [0037] The amount of solid lubricant nanoparticle composition (by weight) sonicated or dispersed in the base may be from about 0.25% to about 5%, suitably 0.5% to about 3%, suitably 0.5% to about 2%, and more suitably 0.75% to about 2%. [0038] The amount of emulsifier (by weight) sonicated or dissolved in the base, depending on the end application, shelf-life, and the like, may be from about 0.5% to about 10%, suitably from about 4% to about 8%, suitably from about 5% to about 6%, and suitably, from about 0.75% to about 2.25%. [0039] The solid lubricant nanoparticle composition may be used, without limitation, as lubricants, coatings, delivery mechanisms, or a combination thereof. The solid lubricant nanoparticle composition may be used, without limitation, as an additive dispersed in a base oil. The composition may also be used, without limitation, to lubricate a boundary lubrication regime. A boundary lubrication regime may be a lubrication regime where the average oil film thickness may be less than the composite surface roughness and the surface asperities may come into contact with each other under relative motion. During the relative motion of two surfaces with lubricants in various applications, three different lubrication stages may occur, and the boundary lubrication regime may be the most severe condition in terms of temperature, pressure and speed. Mating parts maybe exposed to severe contact conditions of high load, low velocity, extreme pressure (for example, 1-2 GPa), and high local temperature (for example, 150-300 degrees C). The boundary lubrication regime may also exist under lower pressures and low sliding velocities or high temperatures. In the boundary lubrication regime, the mating surfaces may be in direct physical contact. The composition may further be used, without limitation, as a lubricant or coating in machinery applications, manufacturing applications, mining applications, aerospace applications, automotive applications, pharmaceutical applications, medical applications, dental applications, cosmetic applications, food product applications, nutritional applications, health related, applications, bio-fuel applications or a combination thereof. Specific examples of uses in end applications include, without limitation, machine tools, bearings, gears, camshafts, pumps, transmissions, piston rings, engines, power generators, pin-joints, aerospace systems, mining equipment, manufacturing equipment, or a combination thereof. Further specific examples of uses may be, without limitation, as an additive in lubricants, greases, gels, compounded plastic parts, pastes, powders, emulsions, dispersions, or combinations thereof. The composition may also be used as a lubricant that employs the solid lubricant nanoparticle composition as a delivery mechanism in pharmaceutical applications, medical applications, dental applications, cosmetic applications, food product applications, nutritional applications, health related applications, bio-fuel applications, or a combination thereof. The various compositions and methods may also be used, without limitation, in hybrid inorganic-organic materials. Examples of applications using inorganic- organic materials, include, but are not limited to, optics, electronics, ionics, mechanics, energy, environment, biology, medicine, smart membranes, separation devices, functional smart coatings, photovoltaic and fuel cells, photocatalysts, new catalysts, sensors, smart microelectronics, micro-optical and photonic components and systems for nanophotonics, innovative cosmetics, intelligent therapeutic vectors that combined targeting, imaging, therapy, and controlled release of active molecules, and nanoceramic-polymer composites for the automobile or packaging industries. [0040J In some embodiments, the ball milling process may create a close caged dense oval shaped architecture (similar to a football shape or fullerene type architecture). This may occur when molybdenum disulphide is milled in a gas or vacuum. Figure 7(A) shows the close caged, dense oval shaped architecture of molybdenum disulphide nanoparticles that have been ball milled in air for 48 hours. [0041] In other embodiments, the ball milling process may create an open ended oval shaped architecture (similar to a coconut shape) of molybdenum disulphide nanoparticles which are intercalated and encapsulated with an organic medium and phospholipids. This may occur when molybdenum disulphide is milled in a gas or vacuum followed by milling in an organic medium. Figure 7(B) shows the open ended oval shaped architecture of molybdenum disulphide nanoparticles that have been ball milled in air for 48 hours followed by ball milling in canola oil for 48 hours. [0042] As shown in the examples, the tribological performance of the nanoparticle based lubricant may be improved. The tribological performance may be measured by evaluating different properties. An anti-wear property may be a lubricating fluid property that has been measured using the industry standard Four-Ball Wear (ASTM D4172) Test. The Four-Ball Wear Test may evaluate the protection provided by an oil under conditions of pressure and sliding motion. Placed in a bath of the test lubricant, three fixed steel balls may be put into contact with a fourth ball of the same grade in rotating contact at preset test conditions. Lubricant wear protection properties may be measured by comparing the average wear scars on the three fixed balls. The smaller the average wear scar, the better the protection. Extreme pressure properties may be lubricating fluid properties that have been measured using the industry standard Four-Ball Wear (ASTM D2783) Test. This test method may cover the determination of the load-carrying properties of lubricating fluids. The following two determinations may be made: 1) load-wear index (formerly Mean-Hertz load) and 2) weld load (kg). The load-wear index may be the load-carrying property of a lubricant. It may be an index of the ability of a lubricant to rninirnize wear at applied loads. The weld load may be the lowest applied load in kilograms at which the rotating ball welds to the three stationary balls, indicating the extreme pressure level that the lubricants can withstand. The higher the weld point scores and load wear index values, the better the anti-wear and extreme pressure properties of a lubricant. The coefficient of friction (COF) may be a lubricating fluid property that has been measured using the industry standard Four-Ball Wear (ASTM D4172) Test COF may be a dimensionless scalar value which describes the ratio of the force of friction between two bodies and the force pressing them together. The coefficient of friction may depend on the materials used. For example, ice on metal has a low COF, while rubber on pavement has a high COF. A common way to reduce friction may be by using a lubricant, such as oil or water, which is placed between two surfaces, often dramatically lessening the COF. [0043] The composition may have a wear scar diameter of about 0.4 mm to about 0.5 mm. The composition may have a COF of about 0.06 to about 0.08. The composition may have a weld load of about 150 kg to about 350 kg. The composition may have a load wear index of about 20 to about 40. The values of these tribological properties may change depending on the amount of solid lubricant nanoparticle composition sonicated or dissolved in the base. [0044] Various features and aspects of the invention are set forth in the following examples, which are intended to be illustrative and not limiting. EXAMPLES Example 1 [0045] Ball milling was performed in a SPEX 800GD machine using hardened stainless steel vials and balls. M0S2 (Alfa Aesar, 98% pure, 700 nm average particle size) and canola oil (Crisco) were used as the starting materials in a ratio of 1 part: MoS2 (10 grams) to 2 parts canola oil (20 grams). The ball to powder ratio was 2 to 1. In other words, the ball weight in the container was 2% by weight and the weight of the M0S2 sample was 1% by weight. M0S2 was ball milled for 48 hours in air followed by milling in canola oil for 48 hrs at room temperature. The nanoparticles were about 50 nm after ball milling. Table 1 summarizes milling conditions and resultant particle morphologies. It was observed that there was a strong effect of milling media on the shape of the ball milled nanoparticles. Dry milling showed buckling and folding of the planes when the particle size was reduced from micron size to nanometer size. However, the dry milling condition used here produced micro clusters embedding several nanoparticles. On the other hand, wet milling showed no buckling but saw de-agglomeration. [00461 Figure 3 shows TEM micrographs of the as-available (700 nm), air milled and hybrid milled (48 hrs in air medium followed by 48 hours in oil medium) M0S2 nanoparticles. Figure 3 (A) represents micron-sized particle chunks of the as-available M0S2 sample off the shelf. These micrographs, particularly Figure 3(B)., represent agglomerates of lubricant nanoparticles when milled in the air medium. Figure 3(B) clearly demonstrates size reduction in air milled M0S2. Higher magnification (circular regions) revealed formation of the disc shaped nanoparticles after milling in the air medium. From Figure 3(C) and 3(D) it may be concluded that the particle size was reduced to less than 30 nm after milling in air and hybrid conditions. Regardless of the occasionally observed clusters, the average size of the clusters is less than or equal to 200 nm. [0047] Hybrid milled samples were dispersed in paraffin oil (from Walmart) and remained suspended without settling. However, the dispersion was not uniform after a few weeks. To stabilize the dispersion and extend the anti-wear properties, phospholipids were added. Around 2 % by weight of soy lecithin phospholipids (from American Lecithin) was added in the base oil. [0048] Figures 4 and 5 show the XRD and XPS spectra of MoS2 before and after ball milling, respectively. XRD spectra revealed no phase change as well as no observable amorphization in the MoS2 after milling.This observation is consistent with the continuous; platelets observed throughout the nanoparticle matrix in TEM analysis for milled material. Broadening of peaks (FWHM) was observed in XRD spectra of MoS2 ball milled in air and hybrid media, respectively. The peak broadening may be attributed to the reduction in particle size. The estimated grain size is 6 nm. This follows the theme of ball milling where clusters consist of grains and sub-grains of the order of 10 nm. XPS analysis was carried out to study the surface chemistry of the as-available and hybrid milled MoS2 nanoparticles. As shown in Figure 3, a carbon (C) peak observed at 285 eV in the as-available MoS2 sample shifted to 286.7 eV. Bonding energies of 286 eV and 287.8 eV correspond to C-0 and C=O bond formation, respectively. The observed binding energy level may demonstrate that a thin layer containing mixed C-O & C=O chains enfolds the MoS2 particles. [0049] Preliminary, tribological tests on the synthesized nanopaiticles were performed on a four-ball machine by following ASTM 4172. The balls used were made of AISI52100 stainless steel and were highly polished. Four Ball Wear Scar measurements using ASTM D4172 were made under the following test conditions: Wear scar diameter (WSD, mm) of each stationary ball was quantified in both vertical and horizontal directions. The average value of WSD from 3 independent tests was reported within ±0.03 mm accuracy. [0050] Four Ball Extreme Pressure measurements using ASTM D2783 were made under the following test conditions: [0051] Three different particles (in w/w ratio) were evaluated for their anti-wear properties as additives in paraffin oil. Figure 6(A) shows the average wear scar measurements for paraffin oil without a nanoparticle additive, paraffin oil with micron sized MoS2, paraffin oil with MoS2 that was milled in air for 48 hours, and paraffin oil with MoS2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours. Figure 6(B) shows the load wear index for paraffin oil without a nanoparticle additive, paraffin oil with micron sized MoS2, paraffin oil with MoS2 that was milled in air for 48 hours, and paraffin oil with MoS2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours. Figure 6(C) shows the COF for paraffin oil without a nanoparticle additive, paraffin oil with micron sized MoS2, paraffin oil with MoS2 that was milled in air for 48 hours, and paraffin oil with MoS2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours. Figure 6(D) shows the extreme pressure data for paraffin oil with micron sized MoS2, paraffin oil with MoS2 that was milled in air for 48 hours, and paraffin oil with MoS2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours. In each test the nanoparticle additive was present in the amount of 1% by weight. Test data from nanoparticle composition additive in base oil [0052] The transfer film in the wear scar, studied using energy dispersive x-ray analysis (EDS), identified the signatures of phosphates in addition to molybdenum and sulphur. Figure 9(a) depicts the base case of paraffin oil without a nanoparticle additive. Figure 9(b) depicts paraffin oil with the molybdenum disulphide nanoparticles and the emulsifier. It shows the early evidences of molybdenum (Mo)-sulphur (S)-phosphorous (P) in the wear track. Iron (Fe) is seen in Figures 9(a) and 9(b), as it is the material of the balls (52100 steel) in the four-ball test. The molybdenum and sulphur peaks coincide aad are not distinguishable because they have the same binding energy. Elemental mapping also showed similar results. Prophetic Examples: [0053] Examples 2-23 are made using a similar method as Example 1, unless specified otherwise. Example 2 [0054] MoS2 (Alfa Aesar, 98% pure, 700 nm average particle size) and canola oil from ADM are used as me starting materials. The MoS2 powder is ball milled for various time conditions, variable ball/powder ratios, and under various ambient conditions, starting with air, canola oil and the subsequent combination of milling in air followed by milling in canola oil. It is also ball milled in different types of organic media. For example, one organic medium that is used is canola oil methyl ester. The processing of this will be similar to the above mentioned example. [0055] Different types of ball milling processes can be used. For instance, in the first step, cryo ball milling in air followed by high temperature ball milling in an organic medium is used. [0056] After the ball milling, the active EP-EA (extreme pressure - environmentally acceptable) particles are treated with, phospholipids that have been mixed with a base oil such as paraffin oil. Example 3 [0057] Molybdenum disulphide is ball milled with boron using a ratio of I part molybdenum disulphide to 1 part boron. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2- boron-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 4 [0058] Molybdenum disulphide is ball milled with copper using a ratio of 1 part molybdenum disulphide to 1 part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2- copper-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 5 [0059] A molybdenum disulphide/graphite (obtained from Alfa Aesar) mixture in the ratio of 1:1 is ball milled. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-graphite-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 6 [0060] A molybdenum disulphide/boron nitride (Alfa Aesar) mixture in the ratio of 1:1 mixture is ball milled. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 7 [0061] A molybdenum disulphide/graphite/boron nitride mixture in the ratio 1:1:1 is ball milled. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-graphite-boron nitride-canola oil) to 2 parts; emulsifier. This is added to the base oil (paraffin oil). Example 8 [0062] A molybdenum disulphide/graphite mixture in the ratio of 1:1:1 is ball milled. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-graphite-boron-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 9 [0063] A molybdenum disulphide/graphite mixture in the ratio of 1:1 is ball milled with copper using a ratio of 1 part molybdenum disulphide/graphite to 1 part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-grapbite-copper-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 10 [0064] A molybdenum disulphide/boron nitride mixture in the ratio of 1:1 is ball milled with boron using a ratio of 1 part molybdenum disulphide/boron. nitride to 1 part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-boron-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 11 [0065] A molybdenum disulphide/boron nitride mixture in the ratio of 1:1 mixture is ball milled with copper using a ratio of 1 part molybdenum disulphide/boron nitride to 1 part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-copper-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 12 [0066] A molybdenum disulphide/boron nitride/graphite mixture in the ratio of 1:1:1 is ball milled with boron using a ratio of 1 part molybdenum disulphide/boron nitride/graphite to 1 part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-graphite-boron- Canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 13 [0067] A molybdenum disulphide/boron nitride/graphite in the ratio of 1:1:1 is ball milled with copper using a ratio of 1 part molybdenum disulphide/boron nitride/graphite to 1 part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-graphite-copper- canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil). Example 14 [0068] Molybdenum disulphide is ball milled with polytetrafluoroethylene (Teflon®) in a ration of 1 part molybdenum disulphide to 1 part Teflon®. This mixture is then added to the base oil (paraffin oil) with a phosphoh'pid emulsifier (soy lecithin). Example 15 [0069] Molybdenum disulphide is ball milled with polytetrafiuoroethylene (Teflon®) in a ration of 1 part molybdenum disulphide to 1 part Teflon®. This mixture is then added to the base oil (paraffin oil) with a phospholipid emulsifier (soy lecithin). Example 16 [0070] Molybdenum disulphide is ball milled with metal additives like copper, silver, lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is further ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part solid lubricant nanoparticles to 1.5 parts esters. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-esters) to 2 parts phospholipid emulsifier. This is added to the base oil (paraffin oil). Example 17 [0071] Molybdenum disulphide is ball milled with metal additives like copper, silver, lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is further ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part solid lubricant nanoparticles to 1.5 parts esters. This is added to the base oil (paraffin oil). Example 18 [0072] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are farther ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part solid lubricant nanoparticles to 1.5 parts esters. An emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-esters) to 2 parts phospholipid emulsifier. This is added to the base oil (paraffin oil). Example 19 [0073] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are further ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part solid lubricant nanoparticles to 1.5 parts esters. This is added to the base oil (paraffin oil). Example 20 [0074] Molybdenum disulphide is ball milled with metal additives like copper, silver, lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is further ball milled in fatty acids (oleic acid) in a ratio of 1 part solid lubricant nanoparticles to 1.5 parts fatty acids. An emulsifler is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-oleic acid) to 2 parts phospholipid emulsifler. This is added to the base oil (paraffin oil). Example 21 [0075] Molybdenum disulphide is ball milled with metal additives like copper, silver, lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is further ball milled in fatty acids (oleic acid) in a ratio of 1 part solid lubricant nanoparticles to 1.5 parts fatty acids. This is added to the base oil (paraffin oil). Example 22 [0076] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are further ball milled in fatty acids (oleic acid) in a ratio of 1 part solid lubricant nanoparticles to 1.5 parts fatty acids. An emulsifler is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-oleic acid) to 2 parts phospholipid emulsifler. This is added to the base oil (paraffin oil). Example 23 [0077] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are further ball milled in fatty acids (oleic acid) in a ratio of 1 part: solid lubricant nanoparticles to 1.5 parts fatty acids. This is added to the base oil (paraffin oil). WE CLAIM: 1. A method of making a nanoparticle composition comprising: (a) dry milling a solid lubricant to produce a dry milled solid lubricant, the dry milled solid lubricant comprising nanoparticles having an average particle dimension of less than 500 nm and wherein at least a portion of the nanoparticles have an open ended oval shape; (b) contacting the dry milled solid lubricant with an organic medium to produce a dry milled nanoparticle composition. 2. The method of claim 1 further comprising wet milling the dry milled nanoparticle composition to produce a wet milled nanoparticle composition. 3. The method of claim 1 or 2 wherein the solid lubricant comprises molybdenum disulphide, tungsten disulphide, graphite, boron nitride or a combination thereof. 4. The method of any one of claims 1-3 wherein the organic medium comprises composite oil, canola oil, vegetable oils, soybean oil, corn oil, ethyl and methyl esters of rapeseed oil, distilled monoglycerides, monoglycerides, diglycerides, acetic acid esters of monoglycerides, organic acid esters of monoglycerides, sorbitan, sorbitan esters of fatty acids, propylene glycol esters of fatty acids, polyglycerol esters of fatty acids, hydrocarbon oils, n-hexadecane, or a combination thereof. 5. The method of any of claims 1 -4 wherein polytetrafluoroethylene, boron nitride, hexagonal boron nitride, soft metals, silver, lead, nickel, copper, cerium fluoride, zinc oxide, silver sulfate, cadmium iodide, lead iodide, barium fluoride, tin sulfide, zinc phosphate, zinc sulfide, mica, boron nitrate, borax, fluorinated carbon, zinc phosphide, boron, or a combination thereof is added to at least one of step (a) or step (b). 6. The method of any of claims 1-5 wherein an anti-oxidant or an anti-corrosion material is added to at least one of step (a) or step (b). 7. The method of any of claims 1 -6 further comprising mixing either the dry milled nanoparticle composition or the wet milled nanoparticle composition with an organic base to produce a nanoparticle-organic base mixture. 8. The method of claim 7 wherein polytetrafluoroethylene, boron nitride, hexagonal boron nitride, soft metals, silver, lead, nickel, copper, cerium fluoride, zinc oxide, silver sulfate, cadmium iodide, lead iodide, barium fluoride, tin sulfide, zinc phosphate, zinc sulfide, mica, boron nitrate, borax, fluorinated carbon, zinc phosphide, boron, molybdenum disulphide, tungsten disulphide, graphite or a combination thereof is added with the organic base. 9. The method of claims 7 or 8 wherein the organic base comprises oil, grease, plastic, gel, wax, silicone, or combinations thereof. 10. The method of any of claims 7-9 wherein an anti-oxidant, an anti-corrosion material or an emulsifier is added with the organic base. 11. The method of any of claims 1-10 wherein the average particle dimension is less than or equal to 100 nm. 12. The method of any of claims 1-11 wherein the dry milling or the wet milling comprises ball milling and is carried out for a time period of from about 12 hours to about 50 hours. 13. A solid lubricant nanoparticle composition produced by the method of any one of claims 1- 12. 14. The composition of claim 13 wherein the nanoparticles are intercalated and/or encapsulated with an organic medium. 15. The composition of claim 13 or 14, wherein the composition comprises from about 0.25% to about 5% nanoparticles by weight. 16. The composition of any of claims 13-15 wherein the composition comprises from about 0.5% to about 2% nanoparticles by weight. 17. The composition of any of claims 13-16 further comprising an emulsifier. 18. The composition of claim 17 comprising from about 0.5% to about 10% emulsifier by weight. 19. The composition of claim 17 comprising from about 0.75% to about 2.25% emulsifier by weight. 20. The composition of any one of claims 16-19 wherein the emulsifier comprises lecithins, phospholipids, soy lecithins, detergents, distilled monoglycerides, monoglycerides, diglycerides, acetic acid esters of monoglycerides, organic acid esters of monoglycerides, sorbitan esters of fatty acids, propylene glycol esters of fatty acids, polyglycerol esters of fatty acids, or a combination thereof. 21. The composition of any one of claims 13-20 further comprising an antioxidant. 22. The composition of claim 21 wherein the antioxidant comprises hindered phenols, alkylated phenols, alkyl amines, aryl amines, 2,6-di-tert-butyl-4-methylphenol, 4,4'-di-tert- octyldiphenylamine, tert-butyl hydroquinone, tris(2,4-di-tert-butylphenyl)phosphate, phosphites, thioesters, or a combination thereof. 23. The composition of any one of claims 13-22 further comprising an anticorrosion agent. 24. The composition of claim 23 wherein the anticorrosion agent comprises alkaline earth metal bisalkylphenolsulphonates, dithiophosphates, alkenylsuccinic acid half-amides, or a combination thereof. 25. A composition comprising close caged dense oval shaped solid lubricant nanoparticies. 26. A composition comprising open ended oval shaped solid lubricant nanoparticles. 27. The composition of claim 25 or 26 wherein the nanoparticles are combined with an organic medium. 28. The composition of claim 27 wherein the nanoparticles are intercalated and/or encapsulated with the organic medium. 29. A method of using the composition of any of claims 13-28 as a lubricant. 30. A method of using the composition of any of claims 13-28 as a coating. A composition that includes solid lubricant nanoparticles and an organic medium is disclosed. Also disclosed are nanoparticles that include layered materials. A method of producing a nanoparticle by milling layered materials is provided. Also disclosed is a method of making a lubricant, the method including milling layered materials to form nanoparticles and incorporating the nanoparticles into a base to form a lubricant.

Full Text

NANOPARTICLE COMPOSITIONS AND METHODS FOR MAKING AND USING
THE SAME
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001 ] This application claims priority to United States Provisional Application No.
60/758,307 filed on January 12,2006, which is hereby fully incorporated by reference.
STATEMENT REGARDING FEDERALLY SPONSORED
RESEARCH OR DEVELOPMENT
[0002] Efforts associated with the subject matter of this application were supported in
part by a grant from the National Science Foundation (NSF/DMI0115532). The government
may have certain rights in any patent issuing from this application.
BACKGROUND
[0003} Over the years, considerable effort has been expended to develop nanostructures
that can be used as lubricants, coatings, or delivery mechanisms. New ways to improve
nanoparticle compositions, their method of manufacture, and their use are sought
SUMMARY
[0004] In one aspect, a composition is described, comprising solid lubricant nanoparticles
and an organic medium.
[0005] In another aspect, nanoparticles comprising a layered material are disclosed.
[0006] In a further aspect, a method of producing a nanoparticle comprising milling
layered materials is provided.
[0007] In yet another aspect, a method of making a lubricant is disclosed, in which the.
method comprises milling layered materials to form nanoparticles and incorporating the
nanoparticles into a base to form a lubricant.

[0008] Other aspects will become apparent by consideration of the detailed description
and accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
[0009] Figure 1 is a diagram illustrating a method of producing solid lubricant
nanoparticles.
[0010] Figure 2 is a diagram illustrating one method of preparing nanoparticle based
lubricants.
[0011] Figure 3 shows transmission electron microscopy (TEM) micrographs of
molybdenum disulpbide particles. Figure 3(A) shows molybdenum disulphide as it is
available, typically from about a few microns to submicron size. Figure 3(B) shows
molybdenum disulphide that has been ball milled in air for 48 hours. Figure 3(C) is a high
resolution electron microscopy image that shows molybdenum disulphide that has been ball
milled in air for 48 hours. Figure 3(D) is a high-resolution transmission electron microscopy
(HRTEM) image that shows molybdenum disulphide that has been ball milled in air for 48
hours followed by ball milling in oil for 48 hours,
[0012] Figure 4 is a graph showing XRD spectra of molybdenum disulphide particles.
Figure 4(A) is the XRD spectra for molybdenum disulphide that has been ball milled in air
for 48 hours followed by ball milling in oil for 48 hours. Figure 4(B) is the XRD spectra for
molybdenum disulphide that has been ball milled in air for 48 hows Figure 4(C) is the XRD
spectra for molybdenum disulphide that has not been ball milled.
[0013] Figure 5 is a graph showing XPS spectra of molybdenum, disulphide particles.
The carbon peak for molybdenum disulphide that has not been ball milled is shown, as well
as the carbon peak for molybdenum disulpbide that has been ball milled in air for 48 hours,
followed by ball millmg in oil for 48 hours.
[0014] Figure 6 shows graphs and bar charts depicting tribological test data for different
additives in paraffin oil. Figure 6(A) shows the average wear scar diameter for a base oil
(paraffin oil), paraffin oil with micron sized M0S2, paraffin oil with M0S2 that was milled in
air for 48 hours, and paraffin oil with M0S2 that was milled in air for 48 hours followed by
milling in canola oil for 48 hours. Figure 6(B) shows the load wear index for paraffin oil

without a nanoparticle additive, paraffin oil with micron sized M0S2, paraffin oil with M0S2
that was milled in air for 48 hours, and paraffin oil with M0S2 that was milled in air for 48
hours followed by milling in canola oil for 48 hours. Figure 6(C) shows the COF for
paraffin oil without a nanoparticle additive, paraffin oil with micron sized M0S2 (c-MoS2),
paraffin oil with M0S2 that was milled in air for 48 hours (d-MoS2), and paraffin oil with
M0S2 that was milled in air for 48 hours followed by milling in canola oil for 48 hours (n-
M0S2). Figure 6(D) shows the extreme pressure data for paraffin oil with micron sized M0S2
(C-M0S2), paraffin oil with M0S2 that was milled in air for 48 hours (d-MoS2), and paraffin
oil with M0S2 that was milled in air for 48 hours followed by milling in canola oil for 48
hours (n-MoS2). In each test the solid lubricant nanoparticle additive was present in the
amount of 1% by weight.
[0015); Figure 7 is a TEM image showing the architecture of molybdenum disulphide
nanoparticles (15-70 nm average size). Figure 7(A) shows the close caged dense oval shaped
architecture of molybdenum disulphide nanoparticles that have been ball milled in air for 48
hours. Figure 7(B) shows the open ended oval shaped architecture of molybdenum
disulphide nanoparticles that have been ball milled in air for 48 hours followed by ball
milling in canola oil for 48 hours.
[00161 Figure 8 is a graph depicting a comparison of wear scar diameters for different
additives in paraffin oil. One additive is crystalline molybdenum disulphide (C-M0S2)-
Another is molybdenum disulphide nanoparticles that were ball milled in air (n- MoS2).
Another additive is molybdenum disulphide nanoparticles that were ball milled in air
followed by ball milling in canola oil and to which, a phospholipid emulsifier was added (n-
M0S2 + Emulsifier).
[00171 Figure 9 shows photographs and graphs produced using energy dispersive x-ray
analysis (EDS) depicting the chemical analysis of wear scar diameters in four-ball
tribological testing for nanoparticle based lubricants. Figure 9(A) shows paraffin oil without
any nanoparticle composition additive. Figure 9(B) shows paraffin oil with molybdenum
disulphide nanoparticles that have been ball milled in air for 48 hours; followed by ball
milling in oil for 48 hours and treated with a phospholipid emulsifier.

DETAILED DESCRIPTION
[0018] Before any embodiments are explained in detail, it is to be understood that the
invention is not limited in its application to the details of construction and the arrangement of
components set forth in the following description or illustrated in the following drawings.
The invention is capable of other embodiments and of being practiced or of being carried out
in various ways. Also, it is to be understood that the phraseology and terminology used
herein is for the purpose of description and should not be regarded as limiting.
[0019] Any numerical range recited herein includes all values from the lower value to the
upper value. For example, if a concentration range is stated as 1% to 50%, it is intended that
values such as 2% to 40%, 10% to 30%, or 1% to 3%, etc., are expressly enumerated in this
specification. These are only examples of what is specifically intended, and all possible
combinations of numerical values between and including the lowest value and the highest
value enumerated are to be considered to be expressly stated in this application.
[0020] Herein described are compositions and methods for making compositions
comprising solid lubricant nanoparticles and an organic medium. Also described are
nanoparticles comprising layered materials. The nanoparticles may be solid lubricant
nanoparticles. The nanoparticles may be made from starting materials or solid lubricant
starting materials. Examples of solid lubricants may include, but are not limited to, layered
materials, suitably chalcogenides, more suitably, molybdenum disulphide, tungsten
disulphide, or a combination thereof. Another suitable layered material is graphite or
intercalated graphite. Other solid lubricants that may be used alone or in combination with
the layered materials are polytetrafluoroethylene (Teflon®), boron nitride (suitably hexagonal
boron nitride), soft metals (such as silver, lead, nickel, copper), cerium fluoride, zinc oxide,
silver sulfate, cadmium iodide, lead iodide, barium fluoride, tin sulfide, zinc phosphate, zinc
sulfide, mica, boron nitrate, borax, fluorinated carbon, zinc phosphide:, boron, or a
combination thereof. Fluorinated carbons may be, without limitation, carbon-based materials
such as graphite which has been fluorinated to improve its aesthetic characteristics. Such
materials may include, for example, a material such as CF.sub.x wherein x ranges from about
0.05 to about 1.2. Such a material is produced by Allied Chemical under the trade name
Accufluor.

[00211 The methods may include milling a solid lubricant feed. In one embodiment, the
solid lubricant feed may be capable of being milled to particles comprising an average
dimension of about 500 nanometers (submicron size) to about 10 nanometers. Suitably, the
particles may have an average particle dimension of less than or equal to about 500
nanometers, suitably less than or equal to about 100 nanometers, suitably less than or equal to
about 80 nanometers, and more suitably less than or equal to about 50 nanometers.
Alternatively, the ball milling may result in milled solid lubricant particles comprising a
mixture, the mixture comprising particles having an average particle dimension of less than
or equal to about 500 nanometers, plus larger particles. Milling may include, among other
things, ball milling and chemo mechanical milling. Examples of ball milling may include dry
ball milling, wet ball milling, and combinations thereof. Ball milling may refer to an
impaction process that may include two interacting objects where one object may be a ball, a
rod, 4 pointed pins (jack shape), or other shapes. Chemo mechanical milling may refer to an
impaction process that may form a complex between an organic medium and a nanoparticle.
As a result of chemo mechanical milling, the organic medium may coat, encapsulate, or
intercalate the nanoparticles.
[0022] In another embodiment, the solid lubricant feed may be dry milled and then wet
milled. An emulsifier may be mixed with a base and added to the wet milled particles. Dry
milling may refer to particles that have been milled in the presence of a vacuum, a gas, or a
combination thereof. Wet milling may refer to particles that have been milled in the presence
of a liquid.
[0023] The solid lubricant nanoparticle composition may further comprise an organic
medium. Examples of organic mediums include, but are not limited to, oil mediums, grease
mediums, alcohol mediums, or combinations thereof. Specific examples of organic mediums
include, but are not limited to, composite oil, canola oil, vegetable oils, soybean oil, corn oil,
ethyl and methyl esters of rapeseed oil, distilled monoglycerides, monoglycerides,
diglycerides, acetic acid esters of monoglycerides, organic acid esters; of monoglycerides,
sorbitan, sorbitan esters of fatty acids, propylene glycol esters of fatty acids, polyglycerol
esters of fatty acids, n-hexadecane, hydrocarbon oils, phospholipids, or a. combination
thereof. Many of these organic media may be environmentally acceptable.

[0024] The composition may contain emulsifiers, surfactants, or dispersants. Examples
of emulsifiers may include, but are not limited to, emulsifiers having a hydrophilic-lipophilic
balance (HLB) from about 2 to about 7; alternatively, a HLB from about 3 to about 5; or
alternatively, a HLB of about 4. Other examples of emulsifiers may include, but are not
limited to, lecithins, soy lecithins, phospholipids lecithins, detergents, distilled
monoglycerides, monoglycerides, diglycerides, acetic acid esters of monoglycerides, organic
acid esters of monoglycerides, sorbitan esters of fatty acids, propylene glycol esters of fatty
acids, polyglycerol esters of fatty acids, compounds containing phosphorous, compounds
containing sulfur, compounds containing nitrogen, or a combination thereof.
[0025] A method of making a lubricant is described. The composition may be used as an
additive dispersed in a base. Examples of bases may include, but are not limited to, oils,
greases, plastics, gels, sprays, or a combination thereof. Specific examples of bases may
include, but are not limited to, hydrocarbon oils, vegetable oils, com oil, peanut oil, canola
oil, soybean oil, mineral oil, paraffin oils, synthetic oils, petroleum gels, petroleum greases,
hydrocarbon gels, hydrocarbon greases, lithium based greases, fluoroether based greases,
ethylenebistearamide, waxes, silicones, or a combination thereof.
[0026] Described herein is a method of lubricating or coating an object that is part of an
end application with a composition comprising at least one of solid mbricant nanoparticles
and an organic medium. Further described is a method of lubricating an object by employing
the composition comprising solid lubricant nanoparticles and an organic medium as a
delivery mechanism.
[0027] Disclosed herein are compositions and methods of preparing nanoparticle based
lubricants that, among various advantages, display enhanced dispersion stability and
resistance to agglomeration. Figure 1 illustrates a method of preparing nanoparticle based
lubricants or compositions. A solid lubricant feed is introduced via line 210 to a ball milling
processor 215. Ball milling is carried out in the processor 215 and the solid lubricant feed is
milled to comprise particles having an average particle dimension of less than or equal to
about 500 nanometers, suitably less than or equal to about 100 nanometers, suitably less than
or equal to about 80 nanometers, and more suitably less than or equal to about 50 nanometers.
Alternatively, the ball milling may result in milled solid lubricant particles comprising a
mixture, the mixture comprising particles having an average particle dimension of less than
or equal to about 500 nanometers, plus larger particles. The ball milling may be high energy

ball milling, medium energy ball milling, or combinations thereof. Additionally, in various
embodiments the ball milling may be carried out in a vacuum, in the presence of a gas, in the
presence of a liquid, in the presence of a second solid, or combinations thereof. The
nanoparticle composition may be removed from the processor via line 220. The nanoparticle
composition may be a nanoparticle based lubricant.
[0028] In alternative embodiments, the ball milling may comprise a first ball milling and
at least one more subsequent ball millings, or ball milling and/or other processing as
appropriate. Suitably, the ball milling may comprise dry milling followed by wet milling.
Figure 2 illustrates a further method 100 of preparing nanoparticle: based lubricants where dry
milling is followed by wet milling. Feed 110 introduces a solid lubricant feed into a ball
milling processor 115 where dry ball milling, such as in a vacuum or in air, reduces the solid
lubricant feed to particles having an average dimension of the size described above. Line 120
carries the dry milled particles to a wet milling processor 125. Via line 160 the dry milled
particles are combined with a composite oil or an organic medium prior to entering the wet
milling processor 125. Alternatively, the organic medium and dry milled particles may be
combined in the wet milling processor 125. In further alternative embodiments (not shown),
the dry milling and wet milling may be carried out in a single processor where the organic
medium is supplied to the single processor for wet milling after initially carrying out dry
milling. In other alternative embodiments, the balls in the ball milling apparatus may be
coated with the organic medium to incorporate the organic medium in the solid lubricant
nanoparticles.
[0029] After wet milling, line 130 carries the wet milled particles to a container 135,
which may be a sonication device. Alternatively, line 130 may carry a mixture comprising
solid lubricant nanoparticles, organic medium, and a complex comprising the solid lubricant
nanoparticles combined with an organic medium.
[0030] In another embodiment, prior to introduction of the wet milled particles into the
eontainer 135, abase may be fed to the container 135 via line 150. Alternatively, the base
. may be supplied to the wet milling processor 125 and the mixing, which may include
sonicating, may be carried out in the wet milling processor 125. In such embodiments the
solid lubricant nanoparticle composition may be employed as an additive and dispersed in the
base. A base may be paired with a solid lubricant nanoparticle composition according to the
ability of the base and the solid lubricant nanoparticle composition to blend appropriately. In

such cases the solid lubricant nanoparticle composition may enhance performance of the
base.
[0031] In a further embodiment, an emulsifier may be mixed with the base. Emulsifiers
may further enhance dispersion of the solid lubricant nanoparticle composition in the base.
The emulsifier may be selected to enhance the dispersion stability of a nanoparticle
composition in a base. An emulsifier may also be supplied to the container 135 via line 140.
In many embodiments, the emulsifier and base are combined in the container 135 prior to
introduction of the wet milled particles. Prior mixing of the emulsifier with the base may
enhance dispersion upon addition of complexes of solid lubricant nanoparticles and organic
medium and/or solid lubricant nanoparticles by homogeneously dispersing/dissolving the
complexes/nanoparticles. In some embodiments, the mixing of the emulsifier and base may
comprise sonicating. Alternatively, the emulsifier may be supplied to the wet milling
processor 125 and the mixing, which may include sonicating, may be carried out in the wet
milling processor 125. The lubricant removed from the container 135 via line 120 may be a
blend comprising the wet milled particles, organic medium, and base. The blend may further
comprise an emulsifier. In other alternative embodiments, additives; may be added to the
nanoparticle based lubricant during interaction with a mating surface.
[00321 In a further embodiment, antioxidants or anticorrosion agents may be milled with
the solid lubricant nanoparticles. Examples of antioxidants include, but are not limited to,
hindered phenols, alkylated phenols, alkyl amines, aryl amines, 2,6-di-tert-butyl-4-
methylphenol, 4,4'-di-tert-octyldiphenylamine, tert-Butyl hydroquinone, tris(2,4-di-tert-
butylphenyl)phosphate, phosphites, thioesters, or a combination thereof. Examples of
anticorrosion agents include, but are not limited to, alkaline-earth metal
bisalkylphenolsulphonates, dithiophosphates, alkenylsuccinic acid half-amides, or a
combination thereof. In another embodiment, biocidals may be milled with the solid
lubricant nanoparticles. Examples of biocidals may include, but are not limited to, alkyl or
kydroxylamine benzotriazole, an amine salt of a partial alkyl ester of an alkyl, alkenyl
succinic acid, or a combination thereof.
[0033] In yet another embodiment, further processing of wet milled particles may
comprise removal of oils that are not a part of a complex with the solid lubricant particles.
Such methods may be suitable for applications that benefit from use of dry particles of solid
lubricant, such as coating applications. Oil and/or other liquids can be removed from wet

milled particles to produce substantially dry solid lubricant particles and complexes. Such
wet milling followed by drying may produce a solid lubricant with reduced tendency to
agglomerate. In specific embodiments, an agent, such as acetone, can be added that dissolves
oils that are not a part of a complex, followed by a drying process such as supercritical
drying, to produce a substantially dry solid lubricant comprising particles treated by milling
in an organic medium.
[0034] Ball milling conditions may vary and, in particular, conditions such as
temperature, milling time, and size and materials of the balls and vials may be manipulated.
In various embodiments, ball milling may be carried out from about 12 hours to about 50
hours, suitably from about 36 hours to about 50 hours, suitably from about 40 hours to about
50 hours, and more suitably at about 48 hours. Suitably, ball milling is conducted at room
temperature. The benefits of increasing milling time may comprise at least one of increasing
the time for the organic medium and solid lubricant nanoparticles to interact; and producing
finer sizes, better yield of nanoparticles, more uniform shapes, and more passive surfaces.
An example of ball milling equipment suitable for carrying out the described milling includes
the SPEX CertiPrep model 8000D, along with hardened stainless steel vials and hardened
stainless steel grinding balls, but any type of ball milling apparatus may be used. In one
embodiment, a stress of 600-650 MPa, a load of 14.9 N, and a strain of 10-3-10-4 per sec may
be used.
[0035] The proportions of the components in a nanoparticle based lubricant may
contribute to performance of the lubricant, such as the lubricant's dispersion stability and
ability to resist agglomeration. In wet milling, suitable ratios of solid lubricant nanoparticles
to organic medium may be about 1 part particles to about 4 parts organic medium by weight,
suitably, about 1 part particles to about 3 parts organic medium by weight, suitably, about 3
parts particles to about 8 parts organic medium by weight, suitably, about 2 parts particles to
about 4 parts organic medium by weight, suitably, about 1 part particles to about 2 parts
organic medium by weight, and suitably, about 1 part particles to about 1.5 parts organic
medium by weight

[0036] Suitable ratios of organic medium to emulsifier in a lubricant including the solid
lubricant nanoparticles may be about 1 part organic medium to less than or equal to about I
part emulsifier, suitably, about 1 part organic medium to about 0.5 parts emulsifier by weight,
or suitably, from about 0.4 to about 1 part emulsifier for about 1 part organic medium by
weight.
[0037] The amount of solid lubricant nanoparticle composition (by weight) sonicated or
dispersed in the base may be from about 0.25% to about 5%, suitably 0.5% to about 3%,
suitably 0.5% to about 2%, and more suitably 0.75% to about 2%.
[0038] The amount of emulsifier (by weight) sonicated or dissolved in the base,
depending on the end application, shelf-life, and the like, may be from about 0.5% to about
10%, suitably from about 4% to about 8%, suitably from about 5% to about 6%, and suitably,
from about 0.75% to about 2.25%.
[0039] The solid lubricant nanoparticle composition may be used, without limitation, as
lubricants, coatings, delivery mechanisms, or a combination thereof. The solid lubricant
nanoparticle composition may be used, without limitation, as an additive dispersed in a base
oil. The composition may also be used, without limitation, to lubricate a boundary
lubrication regime. A boundary lubrication regime may be a lubrication regime where the
average oil film thickness may be less than the composite surface roughness and the surface
asperities may come into contact with each other under relative motion. During the relative
motion of two surfaces with lubricants in various applications, three different lubrication
stages may occur, and the boundary lubrication regime may be the most severe condition in
terms of temperature, pressure and speed. Mating parts maybe exposed to severe contact
conditions of high load, low velocity, extreme pressure (for example, 1-2 GPa), and high
local temperature (for example, 150-300 degrees C). The boundary lubrication regime may
also exist under lower pressures and low sliding velocities or high temperatures. In the
boundary lubrication regime, the mating surfaces may be in direct physical contact. The
composition may further be used, without limitation, as a lubricant or coating in machinery
applications, manufacturing applications, mining applications, aerospace applications,
automotive applications, pharmaceutical applications, medical applications, dental
applications, cosmetic applications, food product applications, nutritional applications, health
related, applications, bio-fuel applications or a combination thereof. Specific examples of
uses in end applications include, without limitation, machine tools, bearings, gears,

camshafts, pumps, transmissions, piston rings, engines, power generators, pin-joints,
aerospace systems, mining equipment, manufacturing equipment, or a combination thereof.
Further specific examples of uses may be, without limitation, as an additive in lubricants,
greases, gels, compounded plastic parts, pastes, powders, emulsions, dispersions, or
combinations thereof. The composition may also be used as a lubricant that employs the
solid lubricant nanoparticle composition as a delivery mechanism in pharmaceutical
applications, medical applications, dental applications, cosmetic applications, food product
applications, nutritional applications, health related applications, bio-fuel applications, or a
combination thereof. The various compositions and methods may also be used, without
limitation, in hybrid inorganic-organic materials. Examples of applications using inorganic-
organic materials, include, but are not limited to, optics, electronics, ionics, mechanics,
energy, environment, biology, medicine, smart membranes, separation devices, functional
smart coatings, photovoltaic and fuel cells, photocatalysts, new catalysts, sensors, smart
microelectronics, micro-optical and photonic components and systems for nanophotonics,
innovative cosmetics, intelligent therapeutic vectors that combined targeting, imaging,
therapy, and controlled release of active molecules, and nanoceramic-polymer composites for
the automobile or packaging industries.
[0040J In some embodiments, the ball milling process may create a close caged dense
oval shaped architecture (similar to a football shape or fullerene type architecture). This may
occur when molybdenum disulphide is milled in a gas or vacuum. Figure 7(A) shows the
close caged, dense oval shaped architecture of molybdenum disulphide nanoparticles that
have been ball milled in air for 48 hours.
[0041] In other embodiments, the ball milling process may create an open ended oval
shaped architecture (similar to a coconut shape) of molybdenum disulphide nanoparticles
which are intercalated and encapsulated with an organic medium and phospholipids. This
may occur when molybdenum disulphide is milled in a gas or vacuum followed by milling in
an organic medium. Figure 7(B) shows the open ended oval shaped architecture of
molybdenum disulphide nanoparticles that have been ball milled in air for 48 hours followed
by ball milling in canola oil for 48 hours.
[0042] As shown in the examples, the tribological performance of the nanoparticle based
lubricant may be improved. The tribological performance may be measured by evaluating
different properties. An anti-wear property may be a lubricating fluid property that has been

measured using the industry standard Four-Ball Wear (ASTM D4172) Test. The Four-Ball
Wear Test may evaluate the protection provided by an oil under conditions of pressure and
sliding motion. Placed in a bath of the test lubricant, three fixed steel balls may be put into
contact with a fourth ball of the same grade in rotating contact at preset test conditions.
Lubricant wear protection properties may be measured by comparing the average wear scars
on the three fixed balls. The smaller the average wear scar, the better the protection.
Extreme pressure properties may be lubricating fluid properties that have been measured
using the industry standard Four-Ball Wear (ASTM D2783) Test. This test method may
cover the determination of the load-carrying properties of lubricating fluids. The following
two determinations may be made: 1) load-wear index (formerly Mean-Hertz load) and 2)
weld load (kg). The load-wear index may be the load-carrying property of a lubricant. It
may be an index of the ability of a lubricant to rninirnize wear at applied loads. The weld
load may be the lowest applied load in kilograms at which the rotating ball welds to the three
stationary balls, indicating the extreme pressure level that the lubricants can withstand. The
higher the weld point scores and load wear index values, the better the anti-wear and extreme
pressure properties of a lubricant. The coefficient of friction (COF) may be a lubricating
fluid property that has been measured using the industry standard Four-Ball Wear (ASTM
D4172) Test COF may be a dimensionless scalar value which describes the ratio of the force
of friction between two bodies and the force pressing them together. The coefficient of
friction may depend on the materials used. For example, ice on metal has a low COF, while
rubber on pavement has a high COF. A common way to reduce friction may be by using a
lubricant, such as oil or water, which is placed between two surfaces, often dramatically
lessening the COF.
[0043] The composition may have a wear scar diameter of about 0.4 mm to about 0.5
mm. The composition may have a COF of about 0.06 to about 0.08. The composition may
have a weld load of about 150 kg to about 350 kg. The composition may have a load wear
index of about 20 to about 40. The values of these tribological properties may change
depending on the amount of solid lubricant nanoparticle composition sonicated or dissolved
in the base.

[0044] Various features and aspects of the invention are set forth in the following
examples, which are intended to be illustrative and not limiting.
EXAMPLES
Example 1
[0045] Ball milling was performed in a SPEX 800GD machine using hardened stainless
steel vials and balls. M0S2 (Alfa Aesar, 98% pure, 700 nm average particle size) and canola
oil (Crisco) were used as the starting materials in a ratio of 1 part: MoS2 (10 grams) to 2 parts
canola oil (20 grams). The ball to powder ratio was 2 to 1. In other words, the ball weight in
the container was 2% by weight and the weight of the M0S2 sample was 1% by weight.
M0S2 was ball milled for 48 hours in air followed by milling in canola oil for 48 hrs at room
temperature. The nanoparticles were about 50 nm after ball milling. Table 1 summarizes
milling conditions and resultant particle morphologies. It was observed that there was a
strong effect of milling media on the shape of the ball milled nanoparticles. Dry milling
showed buckling and folding of the planes when the particle size was reduced from micron
size to nanometer size. However, the dry milling condition used here produced micro
clusters embedding several nanoparticles. On the other hand, wet milling showed no
buckling but saw de-agglomeration.

[00461 Figure 3 shows TEM micrographs of the as-available (700 nm), air milled and
hybrid milled (48 hrs in air medium followed by 48 hours in oil medium) M0S2
nanoparticles. Figure 3 (A) represents micron-sized particle chunks of the as-available M0S2
sample off the shelf. These micrographs, particularly Figure 3(B)., represent agglomerates of
lubricant nanoparticles when milled in the air medium. Figure 3(B) clearly demonstrates size
reduction in air milled M0S2. Higher magnification (circular regions) revealed formation of
the disc shaped nanoparticles after milling in the air medium. From Figure 3(C) and 3(D) it
may be concluded that the particle size was reduced to less than 30 nm after milling in air and
hybrid conditions. Regardless of the occasionally observed clusters, the average size of the
clusters is less than or equal to 200 nm.
[0047] Hybrid milled samples were dispersed in paraffin oil (from Walmart) and
remained suspended without settling. However, the dispersion was not uniform after a few
weeks. To stabilize the dispersion and extend the anti-wear properties, phospholipids were
added. Around 2 % by weight of soy lecithin phospholipids (from American Lecithin) was
added in the base oil.
[0048] Figures 4 and 5 show the XRD and XPS spectra of MoS2 before and after ball
milling, respectively. XRD spectra revealed no phase change as well as no observable
amorphization in the MoS2 after milling.This observation is consistent with the continuous;
platelets observed throughout the nanoparticle matrix in TEM analysis for milled material.
Broadening of peaks (FWHM) was observed in XRD spectra of MoS2 ball milled in air and
hybrid media, respectively. The peak broadening may be attributed to the reduction in
particle size. The estimated grain size is 6 nm. This follows the theme of ball milling where
clusters consist of grains and sub-grains of the order of 10 nm. XPS analysis was carried out
to study the surface chemistry of the as-available and hybrid milled MoS2 nanoparticles. As

shown in Figure 3, a carbon (C) peak observed at 285 eV in the as-available MoS2 sample
shifted to 286.7 eV. Bonding energies of 286 eV and 287.8 eV correspond to C-0 and C=O
bond formation, respectively. The observed binding energy level may demonstrate that a thin
layer containing mixed C-O & C=O chains enfolds the MoS2 particles.
[0049] Preliminary, tribological tests on the synthesized nanopaiticles were performed on
a four-ball machine by following ASTM 4172. The balls used were made of AISI52100
stainless steel and were highly polished. Four Ball Wear Scar measurements using ASTM
D4172 were made under the following test conditions:

Wear scar diameter (WSD, mm) of each stationary ball was quantified in both vertical and
horizontal directions. The average value of WSD from 3 independent tests was reported
within ±0.03 mm accuracy.
[0050] Four Ball Extreme Pressure measurements using ASTM D2783 were made under
the following test conditions:

[0051] Three different particles (in w/w ratio) were evaluated for their anti-wear
properties as additives in paraffin oil. Figure 6(A) shows the average wear scar
measurements for paraffin oil without a nanoparticle additive, paraffin oil with micron sized
MoS2, paraffin oil with MoS2 that was milled in air for 48 hours, and paraffin oil with MoS2

that was milled in air for 48 hours followed by milling in canola oil for 48 hours. Figure
6(B) shows the load wear index for paraffin oil without a nanoparticle additive, paraffin oil
with micron sized MoS2, paraffin oil with MoS2 that was milled in air for 48 hours, and
paraffin oil with MoS2 that was milled in air for 48 hours followed by milling in canola oil
for 48 hours. Figure 6(C) shows the COF for paraffin oil without a nanoparticle additive,
paraffin oil with micron sized MoS2, paraffin oil with MoS2 that was milled in air for 48
hours, and paraffin oil with MoS2 that was milled in air for 48 hours followed by milling in
canola oil for 48 hours. Figure 6(D) shows the extreme pressure data for paraffin oil with
micron sized MoS2, paraffin oil with MoS2 that was milled in air for 48 hours, and paraffin
oil with MoS2 that was milled in air for 48 hours followed by milling in canola oil for 48
hours. In each test the nanoparticle additive was present in the amount of 1% by weight.
Test data from nanoparticle composition additive in base oil

[0052] The transfer film in the wear scar, studied using energy dispersive x-ray analysis
(EDS), identified the signatures of phosphates in addition to molybdenum and sulphur.
Figure 9(a) depicts the base case of paraffin oil without a nanoparticle additive. Figure 9(b)
depicts paraffin oil with the molybdenum disulphide nanoparticles and the emulsifier. It
shows the early evidences of molybdenum (Mo)-sulphur (S)-phosphorous (P) in the wear
track. Iron (Fe) is seen in Figures 9(a) and 9(b), as it is the material of the balls (52100 steel)
in the four-ball test. The molybdenum and sulphur peaks coincide aad are not distinguishable
because they have the same binding energy. Elemental mapping also showed similar results.
Prophetic Examples:
[0053] Examples 2-23 are made using a similar method as Example 1, unless specified
otherwise.
Example 2
[0054] MoS2 (Alfa Aesar, 98% pure, 700 nm average particle size) and canola oil from
ADM are used as me starting materials. The MoS2 powder is ball milled for various time
conditions, variable ball/powder ratios, and under various ambient conditions, starting with
air, canola oil and the subsequent combination of milling in air followed by milling in canola
oil. It is also ball milled in different types of organic media. For example, one organic
medium that is used is canola oil methyl ester. The processing of this will be similar to the
above mentioned example.
[0055] Different types of ball milling processes can be used. For instance, in the first
step, cryo ball milling in air followed by high temperature ball milling in an organic medium
is used.
[0056] After the ball milling, the active EP-EA (extreme pressure - environmentally
acceptable) particles are treated with, phospholipids that have been mixed with a base oil such
as paraffin oil.

Example 3
[0057] Molybdenum disulphide is ball milled with boron using a ratio of I part
molybdenum disulphide to 1 part boron. This mixture is then ball milled with vegetable oil
(canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An
emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-
boron-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil).
Example 4
[0058] Molybdenum disulphide is ball milled with copper using a ratio of 1 part
molybdenum disulphide to 1 part metal. This mixture is then ball milled with vegetable oil
(canola oil) using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An
emulsifier is added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-
copper-canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil).
Example 5
[0059] A molybdenum disulphide/graphite (obtained from Alfa Aesar) mixture in the
ratio of 1:1 is ball milled. This mixture is then ball milled with vegetable oil (canola oil)
using a ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is
added using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-graphite-canola
oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil).
Example 6
[0060] A molybdenum disulphide/boron nitride (Alfa Aesar) mixture in the ratio of 1:1
mixture is ball milled. This mixture is then ball milled with vegetable oil (canola oil) using a
ratio of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added
using a ratio of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-canola
oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil).

Example 7
[0061] A molybdenum disulphide/graphite/boron nitride mixture in the ratio 1:1:1 is ball
milled. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part
solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1
part solid lubricant nanoparticle composition (MoS2-graphite-boron nitride-canola oil) to 2
parts; emulsifier. This is added to the base oil (paraffin oil).
Example 8
[0062] A molybdenum disulphide/graphite mixture in the ratio of 1:1:1 is ball milled.
This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid
lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part
solid lubricant nanoparticle composition (MoS2-graphite-boron-canola oil) to 2 parts
emulsifier. This is added to the base oil (paraffin oil).
Example 9
[0063] A molybdenum disulphide/graphite mixture in the ratio of 1:1 is ball milled with
copper using a ratio of 1 part molybdenum disulphide/graphite to 1 part metal. This mixture
is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid lubricant
nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part solid
lubricant nanoparticle composition (MoS2-grapbite-copper-canola oil) to 2 parts emulsifier.
This is added to the base oil (paraffin oil).
Example 10
[0064] A molybdenum disulphide/boron nitride mixture in the ratio of 1:1 is ball milled
with boron using a ratio of 1 part molybdenum disulphide/boron. nitride to 1 part metal. This
mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part solid
lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1 part
solid lubricant nanoparticle composition (MoS2-boron nitride-boron-canola oil) to 2 parts
emulsifier. This is added to the base oil (paraffin oil).

Example 11
[0065] A molybdenum disulphide/boron nitride mixture in the ratio of 1:1 mixture is ball
milled with copper using a ratio of 1 part molybdenum disulphide/boron nitride to 1 part
metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1 part
solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio of 1
part solid lubricant nanoparticle composition (MoS2-boron nitride-copper-canola oil) to 2
parts emulsifier. This is added to the base oil (paraffin oil).
Example 12
[0066] A molybdenum disulphide/boron nitride/graphite mixture in the ratio of 1:1:1 is
ball milled with boron using a ratio of 1 part molybdenum disulphide/boron nitride/graphite
to 1 part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio
of 1 part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a
ratio of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-graphite-boron-
Canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil).
Example 13
[0067] A molybdenum disulphide/boron nitride/graphite in the ratio of 1:1:1 is ball
milled with copper using a ratio of 1 part molybdenum disulphide/boron nitride/graphite to 1
part metal. This mixture is then ball milled with vegetable oil (canola oil) using a ratio of 1
part solid lubricant nanoparticles to 1.5 parts canola oil. An emulsifier is added using a ratio
of 1 part solid lubricant nanoparticle composition (MoS2-boron nitride-graphite-copper-
canola oil) to 2 parts emulsifier. This is added to the base oil (paraffin oil).
Example 14
[0068] Molybdenum disulphide is ball milled with polytetrafluoroethylene (Teflon®) in a
ration of 1 part molybdenum disulphide to 1 part Teflon®. This mixture is then added to the
base oil (paraffin oil) with a phosphoh'pid emulsifier (soy lecithin).

Example 15
[0069] Molybdenum disulphide is ball milled with polytetrafiuoroethylene (Teflon®) in a
ration of 1 part molybdenum disulphide to 1 part Teflon®. This mixture is then added to the
base oil (paraffin oil) with a phospholipid emulsifier (soy lecithin).
Example 16
[0070] Molybdenum disulphide is ball milled with metal additives like copper, silver,
lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is
further ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part
solid lubricant nanoparticles to 1.5 parts esters. An emulsifier is added using a ratio of 1 part
solid lubricant nanoparticle composition (MoS2-esters) to 2 parts phospholipid emulsifier.
This is added to the base oil (paraffin oil).
Example 17
[0071] Molybdenum disulphide is ball milled with metal additives like copper, silver,
lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is
further ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part
solid lubricant nanoparticles to 1.5 parts esters. This is added to the base oil (paraffin oil).
Example 18
[0072] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are
farther ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part
solid lubricant nanoparticles to 1.5 parts esters. An emulsifier is added using a ratio of 1 part
solid lubricant nanoparticle composition (MoS2-esters) to 2 parts phospholipid emulsifier.
This is added to the base oil (paraffin oil).
Example 19
[0073] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are
further ball milled in vegetable oil based esters (canola oil methyl esters) in a ratio of 1 part
solid lubricant nanoparticles to 1.5 parts esters. This is added to the base oil (paraffin oil).

Example 20
[0074] Molybdenum disulphide is ball milled with metal additives like copper, silver,
lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is
further ball milled in fatty acids (oleic acid) in a ratio of 1 part solid lubricant nanoparticles to
1.5 parts fatty acids. An emulsifler is added using a ratio of 1 part solid lubricant
nanoparticle composition (MoS2-oleic acid) to 2 parts phospholipid emulsifler. This is added
to the base oil (paraffin oil).
Example 21
[0075] Molybdenum disulphide is ball milled with metal additives like copper, silver,
lead etc. in a ratio of 1 part molybdenum disulphide to 1 part metal additive. This mixture is
further ball milled in fatty acids (oleic acid) in a ratio of 1 part solid lubricant nanoparticles to
1.5 parts fatty acids. This is added to the base oil (paraffin oil).
Example 22
[0076] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are
further ball milled in fatty acids (oleic acid) in a ratio of 1 part solid lubricant nanoparticles to
1.5 parts fatty acids. An emulsifler is added using a ratio of 1 part solid lubricant
nanoparticle composition (MoS2-oleic acid) to 2 parts phospholipid emulsifler. This is added
to the base oil (paraffin oil).
Example 23
[0077] Molybdenum disulphide is ball milled. The solid lubricant nanoparticles are
further ball milled in fatty acids (oleic acid) in a ratio of 1 part: solid lubricant nanoparticles to
1.5 parts fatty acids. This is added to the base oil (paraffin oil).

WE CLAIM:
1. A method of making a nanoparticle composition comprising:
(a) dry milling a solid lubricant to produce a dry milled solid lubricant, the dry
milled solid lubricant comprising nanoparticles having an average particle dimension of
less than 500 nm and wherein at least a portion of the nanoparticles have an open ended
oval shape;
(b) contacting the dry milled solid lubricant with an organic medium to produce a
dry milled nanoparticle composition.

2. The method of claim 1 further comprising wet milling the dry milled nanoparticle
composition to produce a wet milled nanoparticle composition.
3. The method of claim 1 or 2 wherein the solid lubricant comprises molybdenum disulphide,
tungsten disulphide, graphite, boron nitride or a combination thereof.
4. The method of any one of claims 1-3 wherein the organic medium comprises composite oil,
canola oil, vegetable oils, soybean oil, corn oil, ethyl and methyl esters of rapeseed oil,
distilled monoglycerides, monoglycerides, diglycerides, acetic acid esters of monoglycerides,
organic acid esters of monoglycerides, sorbitan, sorbitan esters of fatty acids, propylene
glycol esters of fatty acids, polyglycerol esters of fatty acids, hydrocarbon oils, n-hexadecane,
or a combination thereof.
5. The method of any of claims 1 -4 wherein polytetrafluoroethylene, boron nitride, hexagonal
boron nitride, soft metals, silver, lead, nickel, copper, cerium fluoride, zinc oxide, silver
sulfate, cadmium iodide, lead iodide, barium fluoride, tin sulfide, zinc phosphate, zinc
sulfide, mica, boron nitrate, borax, fluorinated carbon, zinc phosphide, boron, or a
combination thereof is added to at least one of step (a) or step (b).
6. The method of any of claims 1-5 wherein an anti-oxidant or an anti-corrosion material is
added to at least one of step (a) or step (b).

7. The method of any of claims 1 -6 further comprising mixing either the dry milled nanoparticle
composition or the wet milled nanoparticle composition with an organic base to produce a
nanoparticle-organic base mixture.
8. The method of claim 7 wherein polytetrafluoroethylene, boron nitride, hexagonal boron
nitride, soft metals, silver, lead, nickel, copper, cerium fluoride, zinc oxide, silver sulfate,
cadmium iodide, lead iodide, barium fluoride, tin sulfide, zinc phosphate, zinc sulfide, mica,
boron nitrate, borax, fluorinated carbon, zinc phosphide, boron, molybdenum disulphide,
tungsten disulphide, graphite or a combination thereof is added with the organic base.
9. The method of claims 7 or 8 wherein the organic base comprises oil, grease, plastic, gel, wax,
silicone, or combinations thereof.
10. The method of any of claims 7-9 wherein an anti-oxidant, an anti-corrosion material or an
emulsifier is added with the organic base.
11. The method of any of claims 1-10 wherein the average particle dimension is less than or
equal to 100 nm.
12. The method of any of claims 1-11 wherein the dry milling or the wet milling comprises ball
milling and is carried out for a time period of from about 12 hours to about 50 hours.
13. A solid lubricant nanoparticle composition produced by the method of any one of claims 1-
12.
14. The composition of claim 13 wherein the nanoparticles are intercalated and/or encapsulated
with an organic medium.
15. The composition of claim 13 or 14, wherein the composition comprises from about 0.25% to
about 5% nanoparticles by weight.

16. The composition of any of claims 13-15 wherein the composition comprises from about 0.5%
to about 2% nanoparticles by weight.
17. The composition of any of claims 13-16 further comprising an emulsifier.
18. The composition of claim 17 comprising from about 0.5% to about 10% emulsifier by
weight.
19. The composition of claim 17 comprising from about 0.75% to about 2.25% emulsifier by
weight.
20. The composition of any one of claims 16-19 wherein the emulsifier comprises lecithins,
phospholipids, soy lecithins, detergents, distilled monoglycerides, monoglycerides,
diglycerides, acetic acid esters of monoglycerides, organic acid esters of monoglycerides,
sorbitan esters of fatty acids, propylene glycol esters of fatty acids, polyglycerol esters of fatty
acids, or a combination thereof.
21. The composition of any one of claims 13-20 further comprising an antioxidant.
22. The composition of claim 21 wherein the antioxidant comprises hindered phenols, alkylated
phenols, alkyl amines, aryl amines, 2,6-di-tert-butyl-4-methylphenol, 4,4'-di-tert-
octyldiphenylamine, tert-butyl hydroquinone, tris(2,4-di-tert-butylphenyl)phosphate,
phosphites, thioesters, or a combination thereof.
23. The composition of any one of claims 13-22 further comprising an anticorrosion agent.
24. The composition of claim 23 wherein the anticorrosion agent comprises alkaline earth metal
bisalkylphenolsulphonates, dithiophosphates, alkenylsuccinic acid half-amides, or a
combination thereof.
25. A composition comprising close caged dense oval shaped solid lubricant nanoparticies.

26. A composition comprising open ended oval shaped solid lubricant nanoparticles.
27. The composition of claim 25 or 26 wherein the nanoparticles are combined with an organic
medium.
28. The composition of claim 27 wherein the nanoparticles are intercalated and/or encapsulated
with the organic medium.
29. A method of using the composition of any of claims 13-28 as a lubricant.
30. A method of using the composition of any of claims 13-28 as a coating.

A composition that includes solid lubricant nanoparticles and an organic medium is disclosed. Also disclosed are nanoparticles that include layered materials. A method of producing a nanoparticle by milling layered materials is provided. Also disclosed is a method of making a lubricant, the method including milling layered materials to form nanoparticles and incorporating
the nanoparticles into a base to form a lubricant.

Documents:

3216-KOLNP-2008-(06-05-2014)-ANNEXURE TO FORM 3.pdf

3216-KOLNP-2008-(06-05-2014)-CORRESPONDENCE.pdf

3216-KOLNP-2008-(06-05-2014)-OTHERS.pdf

3216-KOLNP-2008-(12-11-2013)-CORRESPONDENCE.pdf

3216-KOLNP-2008-(12-11-2013)-OTHERS.pdf

3216-KOLNP-2008-(18-01-2013)-CORRESPONDENCE.pdf

3216-KOLNP-2008-(18-01-2013)-PA.pdf

3216-KOLNP-2008-(27-03-2014)-ANNEXURE TO FORM 3.pdf

3216-KOLNP-2008-(27-03-2014)-CLAIMS.pdf

3216-KOLNP-2008-(27-03-2014)-CORRESPONDENCE.pdf

3216-KOLNP-2008-(27-03-2014)-FORM-13.pdf

3216-KOLNP-2008-(27-03-2014)-FORM-2.pdf

3216-KOLNP-2008-(27-03-2014)-OTHERS.pdf

3216-KOLNP-2008-(27-03-2014)-PETITION UNDER RULE 137.pdf

3216-kolnp-2008-abstract.pdf

3216-KOLNP-2008-AMANDED CLAIMS.pdf

3216-KOLNP-2008-ASSIGNMENT.pdf

3216-kolnp-2008-claims.pdf

3216-KOLNP-2008-CORRESPONDENCE-1.1.pdf

3216-KOLNP-2008-CORRESPONDENCE-1.2.pdf

3216-kolnp-2008-correspondence.pdf

3216-kolnp-2008-description (complete).pdf

3216-kolnp-2008-drawings.pdf

3216-kolnp-2008-form 1.pdf

3216-KOLNP-2008-FORM 13-1.1.pdf

3216-kolnp-2008-form 13.pdf

3216-KOLNP-2008-FORM 18.pdf

3216-KOLNP-2008-FORM 3-1.1.pdf

3216-kolnp-2008-form 3.pdf

3216-kolnp-2008-form 5.pdf

3216-kolnp-2008-international publication.pdf

3216-kolnp-2008-international search report.pdf

3216-KOLNP-2008-OTHERS-1.1.pdf

3216-kolnp-2008-others.pdf

3216-kolnp-2008-pct priority document notification.pdf

3216-kolnp-2008-pct request form.pdf

3216-kolnp-2008-specification.pdf

abstrat-3216-kolnp-2008.jpg

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Patent Number

264166

Indian Patent Application Number

3216/KOLNP/2008

PG Journal Number

50/2014

Publication Date

12-Dec-2014

Grant Date

11-Dec-2014

Date of Filing

06-Aug-2008

Name of Patentee

THE BOARD OF TRUSTEES OF THE UNIVERSITY OF ARKANSAS

Applicant Address

2404 NORTH UNIVERSITY LITTLE ROCK, AR

Inventors:

#	Inventor's Name	Inventor's Address
1	MALSHE, AJAY, P.	4105 GEORGIA ST, SPRINGDALE, AR 72762
2	VERMA, ARPANA	11 SOUTH DUNCAN AVENUE #13, FAYETTEVILLE, AR 72701

PCT International Classification Number

C10M 103/00

PCT International Application Number

PCT/US2007/060506

PCT International Filing date

2007-01-12

PCT Conventions:

#	PCT Application Number	Date of Convention	Priority Country
1	60758307	2006-01-12	U.S.A.