Synthesis, Characterization, and Tribological Evaluation of TiO2

Apr 20, 2016 - The tribological parameters, like mean wear scar diameter, coefficient of ... protecting interacting surfaces significantly from wear a...
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Synthesis, Characterization and Tribological evaluation of TiOReinforced Boron and Nitrogen Co-doped Reduced Graphene Oxide Based Hybrid Nanomaterials as Efficient Antiwear Lubricant Additives Vinay Jaiswal, Kalyani Kalkhanday, Sima Umrao, Rashmi Bala Rastogi, Rajesh Kumar, and Anchal Srivastava ACS Appl. Mater. Interfaces, Just Accepted Manuscript • DOI: 10.1021/acsami.6b01876 • Publication Date (Web): 20 Apr 2016 Downloaded from http://pubs.acs.org on April 26, 2016

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Synthesis, Characterization and Tribological evaluation of TiO2Reinforced Boron and Nitrogen Co-doped Reduced Graphene Oxide Based Hybrid Nanomaterials as Efficient Antiwear Lubricant Additives Vinay Jaiswal†, Kalyani Kalkhanday†, Sima Umrao‡, Rashmi B. Rastogi†*, Rajesh Kumar§ and Anchal Srivastava‡ †

Department of Chemistry, Indian Institute of Technology (Banaras Hindu University) Varanasi-221005, India ‡

§

Department of Physics, Banaras Hindu University, Varanasi-221005, India

Department of Mechanical Engineering, Indian Institute of Technology (Banaras Hindu University) Varanasi-221005, India

Corresponding Author: Rashmi Bala Rastogi Email: [email protected] Fax No. +91 542 2368428

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Abstract The microwave synthesized reduced graphene oxide (MRG), boron-doped-reduced graphene oxide (B-MRG), nitrogen-doped-reduced graphene oxide (N-MRG), boron, nitrogen-co-doped-reduced graphene oxide (B-N-MRG) and TiO2-reinforced-B-N-MRG (TiO2-B-N-MRG) nanomaterials have been synthesized and characterized by various states of the art techniques like Raman, powder XRD, SEM with EDX, HRTEM and XPS. Furthermore, the tribological properties of prepared nanomaterials as antiwear additives in neutral paraffin oil have been evaluated using Four-ball machine at an optimized additive concentration (0.15% w/v). The tribological parameters like mean wear scar diameter (MWD), coefficient of friction (COF) and wear rates revealed that these nanomaterials have potential to be developed as environment friendly sulfated ash, phosphorous and sulfur free (SAPS) antiwear lubricant additives. Friction and wear reducing behaviour of MRG has increased upon successive doping of nitrogen, boron; nitrogen and boron both. Among these additives, B-N-co-doped-MRG shows superior tribological behaviour in paraffin base oil. Besides this, load carrying properties of B-N-co-doped-MRG have significantly improved after its reinforcement with TiO2 nanoparticles. A comparative study of the surface morphology of lubricated track in presence of various additives has been assessed by Scanning Electron Microscopy (SEM) and contact mode Atomic Force Microscopy (AFM). The X-ray photoelectron spectroscopy studies have proved excellent lubrication properties of TiO2-B-N-MRG due to the formation of in situ tribofilm composed of boron nitride, adsorbed graphene layers and tribosintered TiO2 nanoparticles during the tribo-contact. Being sulfur, halogen and phosphorus-free, these graphene based nanomaterials act as green antiwear additives protecting interacting surfaces significantly from wear and tear. Keywords:

B/N/B-N-doped-MRG,

TiO2-B-N-MRG

characterization, Tribological properties, Surface characterization

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nanomaterials,

Material

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1. INTRODUCTION

The lubrication industry needs to be in continuous development to deal with the technological advances and improve the lubricant performance in terms of efficiency and environmental considerations.1-4 A wide variety of lubricant additives have been used to minimize interfacial friction and enhance wear resistant properties. The lubricant is believed to perform these functions by forming a stable interfacial film between the interacting surfaces, thereby reducing friction and wear. The capability of an antiwear additive to reduce friction and wear depends on several factors like additive concentration, composition, molecular structure and interface chemistry with metallic surfaces.5,6 Numerous organic compounds containing sulfur7,8, phosphorus8,9, halogens10,11, boron nitrogen12-14 and their metal complexes15-18 have been widely used as antiwear lubricant additives for several decades. From the environmental perspectives, permissible levels of sulfated ash, phosphorus and sulfur (SAPS) in oil formulations have to be followed according to standard norms.19,20 To meet the above norms several categories of antiwear additives such as Schiff bases21, organoborates22, ionic liquids23-25 and metallic nanoparticles26-29 such as ZnO, CuO, TiO2 and graphene based nanomaterials30-38 are being used now a days from the perspective of engine safety and environment as well. Ever increasing concern regarding energy saving and environment protection has driven an interest towards development of energy-efficient lubricant additives which may possess superior tribological properties but lower emissions than those of the conventionally used additives. The addition of nanomaterials as additives in base lubricant oil is a rapidly progressing field of research because nanomaterials are different from traditional bulk materials due to their extremely small size and high specific surface area.37 Graphene has drawn attention due to its exceptional electrical38,39, optical,40 thermal41 and mechanical properties.38,42 In recent years, graphene based materials have been

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extensively studied for their potential applications in electronic,43 sensor and catalytic properties.44,45Graphene has been recognized as an excellent candidate for reducing adhesion, friction and wear, however, its application in lubrication field has not been explored significantly.46,47 Graphene being two-dimensional material, offers unique friction and wear properties which are not typically seen in conventional materials. It has been demonstrated to act as an effective solid lubricant and/or lubricating oil additive.46 High chemical inertness, extreme strength, and easy shear ability on its densely packed and atomically smooth surface are the major favourable attributes for its remarkable tribological behavior. From a tribological point of view, such extreme mechanical strength is highly desirable for wear protection. Graphene has been shown to be impermeable to liquids and gases, such as water or oxygen, thus slowing down the corrosive and oxidative processes that usually cause more damage to the rubbing surfaces.38 The number of layers, degree of defects and preparation methods etc. play an important role towards its friction, wear and adhesion properties.47 In case of nanomaterials the properties like high specific surface area, low shear strength, excellent Young’s modulus, high thermal stability, good conductivity etc., are desirable from lubrication point of view. A literature survey reveals that graphene possesses all of these desirable properties.47 Kim et al.48 have investigated the micro-scale tribological behavior of multilayer graphene using atomic force microscopy technique and found lower friction values but graphene detached when sliding was performed under an applied load of 5µN for 100 cycles. Berman et al.38 have studied the macro-scale tribological properties of graphene dispersed in ethanol. The results indicate that graphene reduced the friction coefficient greatly but was instantly removed from the sliding surface under an applied load of 5N. Therefore, an intermittent supply of graphene was needed to ensure its presence throughout the whole test period.

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One possible approach to improve the tribological properties of graphene and utilize the above mentioned advantages for tribological applications would be with the hybridgraphene based materials which can implement the synergistic enhancement effect. In the field of tribology, boron and nitrogen based additives have received much attention showing synergistic behavior via formation of in situ protective boron nitride tribochemical film between the steel-steel interface, thereby minimizing friction and wear.21 During past several decades, some 3d-transition metal compounds have been used as reinforcing materials.49-51

Among the 3d-transition elements, titanium dioxide (TiO2)

nanoparticles seem to be fascinating for remarkable tribological behavior.28,52 Therefore, in order to drastically reduce friction and wear simultaneously under a high load, the TiO2reinforced boron, nitrogen-co-doped-microwave assisted reduced graphene oxide (TiO2-B-NMRG) hybrids have been synthesized. Herein, in the present investigation, we have synthesized MRG, boron doped-MRG (B-MRG), nitrogen doped-MRG (N-MRG), boron, nitrogen co-doped-MRG (B-N-MRG) and titanium dioxide reinforced-boron, nitrogen co-doped-MRG (TiO2-B-N-MRG) hybrid materials and characterized them by various state-of-the-art techniques. The resulting graphene based hybrid materials are employed as lubricating additives in neutral paraffin oil and their tribological properties are systematically studied using four-ball lubricant testing machine. The obtained results show that the addition of small amount of MRG in base lube significantly enhanced the tribological properties of base lube. Besides this, doping of heteroatoms nitrogen, boron and co-doped boron and nitrogen to MRG successively enhanced the antiwear properties of the MRG by virtue of forming a protective in situ tribochemical film at the steel-steel interface. Furthermore, the load bearing characteristics of B-N-co-doped-MRG are remarkably improved upon reinforcement with TiO2 nanoparticles. The surface

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characterization of the interacting tribopairs has been done with the help of Scanning Electron Microscopy (SEM) and contact mode Atomic Force Microscopy (AFM). 2.1. EXPERIMENTAL SECTION 2.2. Materials All materials used in the synthesis were of Analytical Reagent grade and employed without any further purification. These include Titanium (IV) butoxide, (C16H36O4Ti, SigmaAldrich, purity >97%), graphite flakes (1-2 mm, NGS Naturgraphit GmbH), Potassium Permanganate (KMnO4, ≥99.0%, Fluka), Ethanol (CH3CH2OH, ≥98% Sigma-Aldrich) and Boric acid (H3BO3, ≥98% Sigma-Aldrich). The other chemicals such as ammonia solution, H2SO4, H3PO4, H2O2, N2H4.H2O, etc. were procured from Merck, India. 2.3. Synthesis of graphene based nanomaterials 2.3.1. Preparation of Graphene Oxide and Reduced Graphene Oxide The graphene oxide (GO) and microwave assisted reduced graphene oxide (MRG) nanomaterials have been recently synthesized by our research group.53 2.3.2. Preparation of TiO2 Nanoparticles TiO2 nanoparticles were synthesized by a sol-gel method with slight modification.54 Concentrated HNO3 (3mL), absolute ethanol (35 mL) and de-ionized water (15mL) were mixed together and to the resulting mixture 17mL of titanium butoxide (50mmol) dissolved in 40mL of absolute ethanol was added drop-wise. It was stirred for 90 min. After 30h the product light white TiO2 gel was filtered and dried at 200°C for 6h. The pale yellow nanoparticles obtained were used for other characterizations and further synthesis of TiO2reinfonced B-N-co-doped reduced graphene oxide. 2.3.3. Preparation of Boron-Nitrogen co-doped Reduced Graphene Oxide

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Boron-doped reduced graphene oxide (B-MRG), nitrogen-doped reduced graphene oxide (N-MRG) and Boron-Nitrogen co-doped reduced graphene oxide (B-N-MRG) have been synthesized by microwave assisted method as reported earlier.53 For the preparation of B-MRG, 500mg of GO was dispersed in ethanol (50ml) in bath sonicator followed by ultra sonicator to make uniform suspension. Boric acid solution (1mg/mL) was added to GO solution under stirring condition and kept at 60°C for 8h. After completion of the reaction, mixture was cooled to room temperature and washed with deionised water. The obtained black powder was dried at 80°C and kept in microwave oven for 3 min at 700 W. The final black powder of B-MRG is very light in weight. Similarly, N-MRG has been synthesized using ammonia solution in place of boric acid. Further, Boron-Nitrogen co-doped reduced graphene oxide (B-N-MRG) has been synthesized by adding ammonia and boric acid solution simultaneously under vigorous stirring and following the above procedure. 2.3.4. Preparation of TiO2-B-N-co-doped Reduced Graphene Oxide For the preparation of TiO2 nanoparticles dispersion, 900mg of TiO2 nanoparticles was well dispersed in 100mL of ethanol (96%) by sonicating it for an hour at ~50°C. B-Ndoped MRG suspension (1mg/mL) in ethanol (96%) was made similarly. The hybrid material was prepared by mixing the both suspensions under stirring condition. The mixture was sonicated for an hour at ~70°C. The hybrid material was filtered and dried at 45°C. The black powder was kept in a microwave oven for 3 min at 700 W and cotton like black product (TiO2-B-N-MRG) was obtained. 2.4. Tribological Characterization Neutral paraffin base oil used in the present investigation possesses the same characteristic properties as that used in our previous studies.21,55 Paraffin oil blends of various synthesized graphene based materials having concentrations 0.00, 0.05, 0.10, 0.15 and 0.20 % (w/v) were made by stirring at 40-50 ᵒC for 2h and thereafter sonicating for 1h at room

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temperature. The entire tribological tests were carried out at an optimized concentration i.e., 0.15% w/v of MRG, B-MRG, N-MRG, B-N-MRG and TiO2-B-N-MRG in paraffin as a base lube. The balls of 12.7 mm diameter made up of AISI 52100 alloy steel having hardness 5961 HRc were used for the tests. Before and after each test, balls were ultrasonically cleaned with n-hexane to remove the residual lubricant and then thoroughly air-dried. The tribological properties of paraffin oil and the nanomaterials dispersed in base lube were tested using Four-Ball Lubricant Tester (Ducom Instruments Pvt. Ltd., Bangalore, India) according to standard test procedures ASTM D4172 and ASTM D5183. In addition to this, the effect of load on mean wear scar diameter (MWD) has also been studied by varying loads 294, 392, 490, 588, 686 and 784 N for 30 min test duration. To study the wear rate, the tests were also performed for different time durations 15, 30, 45, 60, 75 and 90 min respectively at 392N load. In this work, three replicates of friction and wear tests were carried out to minimize data scattering and their average values were reported. The coefficient of friction was obtained by the computer programme automatically. At the end of each test, the wear scar diameter on the each of three horizontal stationary balls was measured by the Image Acquisition System (supplied with the tribotester) and the mean value was termed as mean wear scar diameter (MWD). The details of experimentation and various tribological parameters are provided in ESI [S1]. Morphological features on the worn area of steel balls, lubricated with base lube and its blends with different MRGs, were examined by SEM and AFM. 2.5. Dispersion stability To evaluate the dispersion stability of as prepared various MRGs nanomaterials in liquid paraffin oil, the individual nanomaterial was ultrasonically dispersed in paraffin for 1h. The concentration of these additives in paraffin oil was optimized as 0.15% w/v according to

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the results of tribological tests and these solutions were further diluted 10 times in order to record their UV-Vis spectra. Dispersion stability of the MRGs in base oil was examined by means of absorbance measurement. Absorbance is measured by an ultraviolet-visible (UVVis) spectrophotometer using a UV-2600 spectrophotometer at different time intervals. The photographs of the neutral paraffin oil containing different additives were taken and different settling times were observed. 2.6. Sample Characterization The morphology of the as-synthesized samples was investigated through high resolution transmission electron microscopy (HR-TEM) using a FEI-Tecnai-G2 electron microscope. Raman spectra were obtained with a micro-Raman setup (HR LabRam inverse system, JobinYvon Horiba), the 532 nm line from a frequency doubled Nd:YAG laser (Coherent Compass) was used as excitation wavelength. Multi-Purpose X-ray photoelectron spectroscopy (XPS) (Sigma Probe, Thermo VG Scientific), and X-ray diffraction (XRD) (diffractometer system-XPERT-PRO) using Cu-Kα1 radiation (λ=1.5405980˚A) were employed for characterization of the as-synthesized MRGs. Scanning electron microscope (SEM) images of the worn surface of the steel balls were taken using a ZEISS SUPRA 40 electron microscope. A contact mode atomic force microscope (Model no. BT 02218, Nanosurf easyscan2 Basic AFM, Switzerland) was used to investigate the roughness of the worn surfaces with the Si3N4 cantilever (Nanosensor, CONTR type) having a spring constant of 0.1 Nm-1and tip radius more than 10 nm. 3. RESULTS AND DISCUSSION 3.1. Morphology and Microstructure of MRGs The SEM images of MRG, B-N-MRG and TiO2-B-N-MRG are presented in Figure 1. Layered structure of graphene is conspicuous from the SEM images of MRG, Figure1a. After

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co-doping of B and N to MRG (Figure1b) the morphology appears to be almost unchanged. In Figure 1c, it is clearly visible that TiO2 nanoparticles (2-15 nm) are decorated on graphene sheet. Further, to confirm the chemical composition of TiO2-B-N-MRG, energy dispersive Xray spectra (EDX) of as synthesized samples were recorded. EDX spectrum of TiO2-B-NMRG (Figure 1c) clearly shows strong signal for carbon but the signals for B and N separately could not be identified owing to their small amount as dopant and close atomic number with C. The quantitative EDX results, tabulated in inset of Figure 1c reveal an approximate stoichiometric composition as TiO2-B-N-MRG. The signals from oxygen (~10.27 % atomic weight) and titanium (~14.79 % atomic weight) confirmed the presence of TiO2 nanoparticle on the graphene sheet. The morphology of all samples was further characterized by TEM and HRTEM also. TEM images of MRG, B-N-MRG and TiO2-B-N-MRG (Figures 2(a), (c) and (e)) show transparent and layered structure. After co-doping of B and N, slight changes are observed in graphene morphology. The HRTEM images (Figures 2(b) and (d)) show the lattice spacing of graphene sheets in MRG and B-N-MRG as 0.339 and 0.34nm respectively due to 002 plane of graphene. Figures 2e and 2f display the TEM and HRTEM images of TiO2-B-NMRG exhibiting clearly TiO2 nanoparticles on the surface of doped graphene. The size of TiO2 nanoparticles is found to be in the range of 2-15 nm with several crystal planes which are randomly oriented across the particles. The high-resolution TEM image of the TiO2-BN-MRG exhibits the lattice fringes of the TiO2 (0.352 nm) corresponding to the TiO2 (101) plane (JCPDS No. 21-1272) and lattice spacing of graphene sheets was found to be 0.343nm corresponding to 002 plane of graphene. Typical X-ray diffraction (XRD) patterns of MRG, B-MRG, N-MRG, B-N-MRG and TiO2-B-N-MRG are shown in Figure 3a. In the diffraction pattern of MRG, the peak around 26.13° corresponds to the (002) reflection (interlayer spacing of 0.35 nm) while the other

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peak at 43.7° having lower intensity compared to the previous peak corresponds to the (100) reflection implying the formation of turbostratic graphitic carbon.56 The XRD pattern of TiO2 nanoparticles reported six distinct diffraction peaks at 20.8°, 25.1°, 30.4°, 37.9°, 48.2°, and 54.2° indexed with the (102), (101), (101), (004), (200) and (105) planes of TiO2 (JCPDS no. 21-1272) respectively, in a fcc crystal structure. The presence of distinct broad peaks confirms the high purity of the prepared nanoparticles with small size. The interplanar spacing of d002 plane, crystallite size and lattice parameters of MRG, B-MRG, N-MRG and B-N-MRG samples, calculated using Bragg’s law and Debye-Scherrer’s formula show nonremarkable variations. Furthermore, it can be found that the XRD patterns of TiO2-B-N-MRG show peaks which are similar to the diffraction pattern of TiO2. This indicates that the anatase phase is predominant in the composite sample. The XRD pattern of TiO2-B-N-MRG exhibits clear peaks of pure TiO2, but the peak at 25° in TiO2 is broadened due to its superimposition with the diffraction peak of MRG at 24.04°. The highlighted diffraction peak in Figure 3a (~25°) deconvoluted into three diffraction peaks corresponding to anatase, rutile phase and graphitic. Figure 3b shows deconvoluted peaks corresponding to (101) (003) and (002) reflection planes. Additional structural information of the MRG, N-MRG, B-MRG, B-N-MRG and TiO2-B-N-MRG nanomaterials was availed from Raman spectroscopy using 532 nm laser excitations are shown in Figure S1. The D peak at approx. 1359 cm-1 is due to a breathing mode of A1g symmetry, which is endorsed to the presence of disorder in graphene sheets. The G peak at ca. 1586 cm-1 is a doubly degenerate phonon mode (E2g symmetry) for sp2 carbon network which is showcase of graphitic nature of compound.57 The 2D band in Raman spectra of graphene is overtone of D band and it is susceptible to the stacking order of graphene layers resulting in turbostratic graphite, which lacks a stacking order of graphene layers. Presence of this band shows turbostratic graphite. In graphene with multilayers, 2D

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band is ascribed to the presence of 2-D and 3-D graphite structure.58 Since 2D band originates from a process where two phonons with opposite wave-vectors satisfy momentum conservation, therefore no defects are required for the activation of 2D bands and this peak is always present in all samples. The ratio of intensity of D and G band (ID/IG ratio), demonstrates the density defects and hence the degree of disorder in the structure. The ID/IG ratio is found to increase from 0.4159 in graphene to 0.5506 and 0.5852 after doping of B and N respectively. This confirms that disorder has appreciably increased in graphene sheet.59 However, after co-doping of B and N and decoration of TiO2 nanoparticle, the ID/IG ratio is decreased from 0.4159 to 0.2625 and 0.1629 which may be due to rearrangement of sp2 carbon and more reduction of oxygen. Raman spectrum of TiO2 nanoparticles shows five Raman peaks, FigureS2. The peaks observed around 148, 267, 402, 514 and 638 cm-1 are assigned to the E(g), E(g), B(1g), B(1g)+ A(1g), and the E(g) modes of anatase phase respectively. Further, the chemical structures of MRG and TiO2-B-N-MRG were studied using XPS measurements. XPS survey of both MRG and TiO2-B-N-MRG (Figure S3) shows the presence of B, N and Ti elements with carbon and oxygen. Atomic % of C, O, B, N and Ti is 87.18, 8.07, 1.56, 2.42 and 0.77 respectively. Moreover, the core-level spectra of TiO2-B-NMRG have been deconvoluted with best fitting parameters using peak fit software as shown in Figure 4. Figure 4(a) shows that the core level spectra of C1s have been deconvoluted into six peaks with binding energies of 283.9, 284.7, 285.1, 286.3, 288.2 and 290.6 eV corresponding to B-C, sp2C–sp2C, N-sp2C, N-sp3C, C=O, and O-C=O bonds respectively.60 B1s core level spectra can be deconvoluted into three components showing peaks at 191.5, 192.3 and 193.2 corresponding to B-C, B-CO2 and B–O bonds respectively as shown in Figure 4b.61 Figure 4c shows that N1s core level spectrum deconvoluted into three peaks corresponding to pyridinic N (~ 398.5 eV), pyrrolic N (~ 399.5 eV) and graphitic N

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(398.5eV). Ti 2p core-level spectrum shows the presence of Ti 2p3/2 and Ti 2p1/2 levels, Figure 4d.59 3.2. Dispersion stability of MRGs in paraffin oil The dispersion stability of MRG, B-MRG, N-MRG, B-N-MRG and TiO2-B-N-MRG nanomaterials in paraffin oil was evaluated and compared using UV-visible spectroscopy. Figure S4a shows the relative absorbance of ultrasonically dispersed different samples in base oil w.r.t. time. The relative absorbance of MRGs in base oil reduces with time before getting settled down. The sedimentation of the MRG is comparatively much faster than the doped MRGs. With the expense of time, the relative absorbance of each nanomaterial decreases. Initially, upto 12h there is a marginal change (upto 10%) in the suspension stability of TiO2B-N-MRG and B-N-MRG whereas this change becomes significant (upto 18-25%) in case of B-MRG, N-MRG and MRG. However, after a long period of time exposure (48h), the relative absorbance of the B-N-MRG, TiO2-B-N-MRG is maintained respectively at ~0.69 and ~0.70 which is much higher than the relative absorbance of MRG, B-MRG and N-MRG respectively ~0.48, ~0.59 and ~0.59. Thus, the dispersion stability of B-N-MRG and TiO2-BN-MRG is comparatively much higher than the pure MRG, B-MRG/N-MRG. Figure S4b shows optical images of different samples dispersed in paraffin oil at different periods. Initially, after sonication the different MRGs samples are well-dispersed in the base oil. After 48h of time exposure, the lubricants containing MRG, B-MRG and N-MRG appear to be almost settled down. On the other hand B-N-MRG and TiO2-B-N-MRG remain suspended in the base lube up to 48h showing their maximum dispersion stability. Thus, the sedimentation plots and images of various MRG samples proved that the dispersion stability of graphene in paraffin oil can be improved upon co-doping with B and N and further reinforcement with TiO2 nanoparticles. 3.3. Tribological Properties

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3.3.1. Additive optimization Antiwear behavior of the additive molecule depends on its concentration in the base lube. Therefore, it is important to optimize the additive concentration before conducting the tribological test. Figure 5 shows the variation of mean wear scar diameter (MWD) with additive concentration at a load of 392N for 60 min test duration in paraffin as a base lube. Figure 5 shows the blends of MRG and B-N-MRG in paraffin oil significantly reduced the MWD values and thereby improved the antiwear properties of base oil at each concentration. The MWD value decreases from 0.733 mm to 0.702 mm (in case of MRG) and 0.699 mm (in case of B-N-MRG) at the additive concentration of only 0.05% w/v. The antiwear performance of blends is further improved upon increasing their concentration to 0.10%. At this concentration, the advantage of B-N-co-doping in MRG over MRG can be clearly seen. It may be associated with the layered structure of MRG having boron and nitrogen atoms which have low shear strength and prevent metal-metal adhesion. Under operating conditions, these heteroatoms may interact with each-other and/or with the steel surface to form insitu protective films.62 On further increasing the concentration up to 0.15%, the lowest values of MWD are obtained in case of both MRG (0.655mm) and B-N-MRG (0.490mm). However, on increasing the concentration from 0.15-0.20 %, the MWD values began to slightly increase in each case which may be due to corrosive wear. Thus, the optimized additive concentration has been found to be 0.15% w/v and hence, all the tribological tests were performed at this optimized concentration. 3.3.2. Antiwear Properties The synthesized graphene based hybrid materials were evaluated to probe their lubrication potential using paraffin as a base lube. The comparison of the mean wear scar diameter (MWD) along with average coefficient of friction (COF) values of the

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corresponding steel balls lubricated with base oil and blends of B-MRG, N-MRG, B-NMRG, TiO2-B-N-MRG hybrid materials in paraffin oil under the load of 392N for 60 min test duration at 1200 rpm (ASTM D4172) are shown in Figure 6 . The value of MWD and average COF for paraffin oil was about 0.733mm and 0.0756, respectively. Addition of all nanomaterials as additive to the base lube significantly reduces the both MWD and COF. There is slight improvement in the antiwear properties of the base oil in presence of MRG which reduce the value of MWD and COF by only 10.64 and 02.91%, respectively. The extent of improvement in these values is increased upon doping of individual boron and nitrogen atoms to MRG. However, in case of boron-nitrogen-co-doped MRG these values increase further to a greater degree. The obtained results suggest that the blend of B-N-MRG has better lubricating behavior than the individual B-MRG and N-MRG which may be due to synergistic lubricating action of the boron and nitrogen atoms present in B-N-MRG. Under tribostress conditions these atoms react with each other and/or with the interacting steel surface to form protective in situ tribochemical film/s which may be composed of boron nitride, B2O3 etc. The tribofilm separates the metal-metal contact at interface thereby reducing friction and wear.21 Low shear strength and high thermal conductivity of these protective tribofilms are beneficial for the excellent tribological properties.12 The lubricant also acts a as heat transfer medium which reduces the asperity temperature at steel-steel interface and prevents the surface from adhesion. Furthermore, the effect of reinforcement of B-N-MRG with TiO2 nanoparticles is clearly evident from Figure 6 as it exhibits phenomenal reduction in the MWD and COF values about 50.88 and 25.40%, respectively which is much larger than those obtained in case of B-N-MRG (33.15 & 20.37%). The exceptional tribological behavior of TiO2-B-N-MRG hybrid nanomaterial in paraffin oil is the cumulative effect of layered structure of MRG, synergistic interaction of boron and nitrogen; and the most important is the TiO2 nanoparticles which act as nanobearings between steel-steel

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interfaces. Addition of even a very small concentration of graphene based hybrid materials to the base lube is sufficient for the formation of protective tribofilms on steel surfaces. Figure 7 illustrates the variation in the friction coefficient of steel surface supplemented with paraffin oil and blends of various graphene based hybrid nanomaterials in paraffin oil with time. One can see that the friction coefficient value of the base oil varies considerably during the entire test duration and its values are higher and unstable than those for the base oil with additives. There is significant reduction in the COF for the blends of graphene based nanomaterials except MRG. The exceptional increase in the COF values of MRG with time may be due to the consequences of agglomeration of MRG under high temperature and pressure which hampered their uninterrupted supply to the interfaces. On the other hand, the friction coefficient of the base oil containing N-MRG, B-N-MRG and TiO2B-N-MRG remarkably decreases with time. This test confirms the formation of the tribofilm formed by these additives even at such a low concentration. In presence of additives, high COF values are obtained during initial few minutes of the sliding time and later on in all cases it gradually decreases and/or remains constant except MRG. The lowest and almost stable friction coefficient values are obtained for the surface lubricated with TiO2-B-N-MRG which may be due to the presence of TiO2 nanobearings at tribocontact thereby reducing friction. The initially obtained high friction values may be attributed to the absence of any tribofilm between steel-steel interfaces because formation of tribofilm is time dependent.63 The stability of the friction coefficient with time is a very important property in mechanical systems needed for their functionality during the service life.6 In order to investigate wear rate of the steel-steel surface supplemented with graphene based hybrid nanomaterials in paraffin oil the test has been also performed for different 15, 30, 45, 60, 75 and 90 time durations under the load of 392N at 0.15% w/v concentration. The obtained MWD values as a function of sliding time for different additives has been plotted in

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Figure S5. To estimate wear more accurately it is important to investigate the variation of mean wear volume with respect to time instead of mean wear scar diameter.55 Figure S6 shows the variation of mean wear volume with different sliding time and the linear regression model is fitted to obtained wear rate. The value of running-in and steady-state wear rate has been mentioned in Table 1 and corresponding plots have been incorporated into Figures S7 and S8. The values of running-in and steady-state wear rates are found to be very high in absence of additives; however, in presence of MRG, B-MRG, N-MRG, B-N-MRG and TiO2B-N-MRG hybrid nanomaterials these values are successively reduced in each case. Besides this, the values of running-in wear rate in each case are found to be larger than those of corresponding steady-state wear rate. The observed behavior of wear rates in presence of additives follows the same trend as discussed above. The lowest values of running-in and steady-state wear rates are found for the surface added with TiO2-B-N-MRG hybrid nanomaterials which reduces these values upto 24 and 67 folds, respectively in comparison to base lube. The life of engineering components is assessed on the basis of steady-state wear rate. Thus, on the basis of such a tremendously low steady-state wear rate, one can recommend these TiO2-B-N-MRG hybrid nanomaterials for potential application in the tribological industries for wide range of lubrication. 3.4. Effect of load Figure 8 shows relationship between the applied load and mean wear scar diameter of different synthesized additives in paraffin oil at 0.15% w/v for 30 min sliding time. The increase of applied load results in the increase in the MWD value. This may be due to the fact that with increase of applied load, the film thickness between the contacting surfaces decreases resulting into the increase in the direct contact of asperities.64 The values of MWD are found to be much larger in case of surface lubricated with base oil at each tested load than the surface lubricated with additives. Initially at 294N load, the MWD is very large in the

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absence of additives but in the presence of MRG, B-MRG and N-MRG it is remarkably reduced. The value of MWD is further reduced upon co-doping of boron and nitrogen in MRG and reaches the minimum value for the blend of TiO2-B-N-MRG. This behavior of different additives follows the same order till 588N except MRG, where a sudden increase in the MWD has been observed. Beyond 588N load the thin film fails to sustain the load in the case of blends of B-MRG and N-MRG in paraffin oil. On further increasing the load up to 686N, admixtures of B-N-MRG and TiO2-B-N-MRG successfully bear the load, however, the MWD values are found to be much larger in the former case than the latter e. Moreover, as expected the load bearing ability of TiO2-B-N-MRG is found to be maximum up to 784N. Application of MRG as lubricating oil additive under extreme conditions has been limited due to its poor adherence with sliding surface.38 The load bearing ability of MRG is improved upon doping of individual boron and nitrogen atom which enhanced the adherence property of the MRG. The adherence property of MRG is further improved upon co-doping of B and N atoms which clearly reflects that the nature of tribofilm/s formed for the surface lubricated with B-N-MRG is entirely different from the film/s generated in case of surface lubricated with B-MRG and N-MRG. The excellent load bearing ability of B-N-MRG may be due to the fact that under lubricating conditions it adsorbed on the sliding surfaces and under extreme conditions B-N-MRG decomposed to form in situ protective tribochemical film which is composed of boron nitride as it was obtained in our previous published work.21 However, TiO2 reinforced MRG hybrid nanomaterial further enhanced the load bearing ability of B-N-MRG which is due to the presence of additional TiO2 nanobearings providing low shear strength between steel-steel interfaces. Therefore, these hybrid nanomaterials exhibit excellent antiwear properties in a relatively wide range of applied load. 3.5. Coefficient of friction test

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The steady-state period is very important for the life-span of all engineering components under tribostress. In order to investigate the behavior of different graphene based hybrid nanomaterials towards steady-state coefficient of friction, the standard test ASTM D5183 has been performed. Prior to perform steady-state COF, initially the test has been conducted under the load of 392N at 600 rpm for 60 min time duration with heating at 75 ᵒC to ensure the completion of running-in period for all the studied additives. The obtained results are mentioned in Figure 9. On comparing Figure 6 with Figure 9, it is evident that on decreasing the sliding speed (from 1200 to 600 rpm) MWD values decrease whereas COF values somewhat increase in all cases. After this, the steady-state COF test has been performed for all the tested additives by varying the applied loads stepped by 98N at each 10 min of time and their corresponding values are displayed in Figure 10. Initially, the value of frictional torque is found to be somewhat higher in absence of additives than the surface lubricated with additives. As the load and time increase, the difference in the frictional torque values between base lube and blends of additives become very large. At each load, lower and stable frictional torque values w.r.t. time is observed in presence of additives. Besides this, there is drastic increase in the frictional torque value in case of paraffin oil at 1078N load causing seizure between tribopairs. However, for the tribopairs lubricated with MRG, BMRG, N-MRG, B-N-MRG and TiO2-B-N-MRG, the seizure occurred at 1078, 1274, 1274, 1372 and 1470 N load, respectively, which is due to the rupture of tribofilm resulting break in steady-state. These results further prove the friction-reducing and antiwear properties of hybrid graphene based nanomaterials under the extreme conditions. The findings of this test also strengthen the objective of the present communication that the sustainability of MRG towards higher load conditions should be enhanced. That is witnessed by the observed synergistic interaction of B-N-co-doped-MRG at steel-steel interface and further

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enhancement in tribological properties due to TiO2 nanobearings in TiO2 reinforced B-N-codoped-MRG. 3.6. Surface Characterization The surface morphology of wear scar formed on sliding surfaces has been studied by scanning electron microscopy (SEM) and contact mode atomic force microscopy (AFM) techniques. Figure 11 shows SEM images of worn steel surfaces lubricated with base oil and blends (0.15 % w/v) of each additive under the load of 392N for 60 min test duration. The worn area in presence of base oil exhibited very large MWD (0.733mm) with huge surface destruction attributed to the plastic deformation on the steel surface under the test conditions. However, in presence of the additives, remarkable smoothening of surfaces has been observed which is in conformity with the order of antiwear properties of different additives. From the SEM images (inset), it can be clearly seen that the value of MWD is successively reduced upon doping of B/N, co-doped-B-N and finally TiO2-reinforced co-doped-B-N to MRG which correlates well with their observed tribological behavior. There are some padlike structures visible on the surface of wear track lubricated with additives which are supposed to be due to adsorbed graphene sheets under the tribostress. In order to prove the suitability of these hybrid graphene based nanomaterials at higher load, the SEM-images of the wear track were also taken at higher load i.e., 588N for 30 min of test duration. Figure S9 shows the SEM-images of surface added with blends of MRG, B-MRG, B-N-MRG and TiO2-B-N-MRG. These images also exhibit the effect of dopant and/or reinforcement of TiO2 to MRG by reducing corresponding MWD values to a greater extent. The surface topography of worn steel surfaces in presence and absence of graphene based materials in base oil has been compared using contact mode AFM. The 2D and 3D AFM-images along with surface roughness values (line roughness; Rq and area roughness;

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Sq) of steel surfaces under the load of 392N for 60 min. time duration are displayed in Figure 12. The line roughness of each of the worn surfaces has been taken across the sliding direction. The values of surface roughness are found to be much higher in absence of additives (Sq= 674 nm; Rq= 670 nm) whereas in presence of MRGs these values are surprisingly reduced (ranges from Sq= 105-40 nm; Rq= 149-39 nm). Among the studied MRGs, both B-N-MRG and TiO2-B-N-MRG show the maximum reduction in surface roughnessess up to ̴ 94%. The AFM-images lubricated with these additives clearly show some pad-like deposition along with sliding direction. The pad like deposition on the sliding track is a consequence of adsorbed nanomaterials and/or synergistic effect of co-doped B-NMRG forming in situ tribochemical film on the steel-steel interface. The AFM-observation also strengthens the SEM results under the similar test conditions. The AFM-images of studied graphene based additives are also taken at 588N load for 30 min test duration, Figure S10. These AFM-images show the similar trend towards the surface smoothening as observed in the above case. Thus, these nanomaterials have potential to be used under high load conditions, too. 3.7. Tribochemistry In order to explore the chemical composition of tribofilm, the XPS spectra of the steel surface lubricated with TiO2-B-N-MRG under ASTM D5183 has been recorded. Each spectrum has been deconvoluted with XPS Peak software after subtracting the Shirley background. Figure 13 shows the curve fitted XPS-spectra of C 1s, B, 1s, N 1s, O1s, Ti 2p and Fe 2p of the lubricated steel surface. Figure 13(a) shows that the core level spectra of C1s have been deconvoluted into three similar peaks as observed in case of TiO2-B-N-MRG with binding energies of 284.8, 286.3 and 287.9 eV corresponding to sp2C–sp2C, N-sp3C and C=O moieties respectively.60 Besides this, on combining the binding energies of B 1s (Figure 13

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(b)) with N 1s signal (Figure 13 (c)) appearing at 189.8 eV and 398.6 eV, respectively confirmed the formation of boron nitride

between tribopairs.65,66 However, there is no

significant shift in the binding energies of Ti 2p1/2 and Ti 2p3/2 signals showing that TiO2 nanoparticles are tribosintered on the metallic surface (Figure 13 (d)).59 The iron of the steel surface was oxidized to Fe2O3 under lubricating conditions which is evident from the observed signals 711.8 eV for Fe 2p and 530.6 eV for O 1s spectra (Figures 13 (e) and (f)).67 Therefore, it can be reasonably concluded that the TiO2-B-N-MRG nanomaterial has proven its excellent tribological behavior by virtue of forming in situ protective boron nitride tribofilm and graphene layers deposited on the steel-steel interfaces under tribostress conditions. The reinforced TiO2 nanoparticles act as nanobearings to form uniform layer which prevents direct meal-metal contact and thus reducing friction and wear. 3.8. Proposed mechanism Based on the observed tribological and surface characterization results, the excellent tribological properties of the studied MRGs nanomaterials acting as a novel additive in paraffin have been proved. Among studied MRGs, both B-N-MRG and TiO2-B-N-MRG nanomaterials exhibit much improved tribological properties. The enhanced tribological properties of B-N-co-doped-MRG and TiO2-reinforced-B-N-co-doped-MRG are due to the following reasonsInitially, these nanomaterials get uniformly adhered in between the tribopairs. Under high stress conditions, the anchoring behavior of graphene is poor in comparison to doped and reinforced graphene based nanomaterials.38 Under extreme conditions (high load and high temperature), these doped elements boron and nitrogen reacted themselves to form in situ protective tribofilm to minimize asperity-asperity adhesion which is evident from its much smaller MWD value in case of B-N-co-doped-MRG. The formation of protective tribofilm is time-dependent and it is facilitated as the time increases.63 Furthermore, in case of

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TiO2-B-N-MRG, the TiO2 nanoparticles deposited in between MRG surfaces prevent agglomeration. Being spherical in shape, TiO2 nanoparticles act as nanobearings in between the both MRG layers and tribopairs, therefore, facilitate the sliding phenomenon of MRG layers under high stress conditions reducing friction and wear. Thus, excellent tribological properties of B-N-codoped-MRG may be due to the formation of in situ BN tribofilm under tribostress condition on the sliding surfaces. These properties are further enhanced in case of TiO2-reinforced-B-N-MRG nanomaterial (Figure 13) due to TiO2 nanobearings and/or tribosinterization. CONCLUSIONS The microwave synthesis of few layered thick reduced graphene oxide (MRG), BMRG, N-MRG, B, N-co-doped-reduced graphene oxide (B-N-MRG) and TiO2-reinforced-BN-MRG (TiO2-B-N-MRG) nanomaterials have been successfully synthesized and characterized by various states of the art techniques like Raman, powder XRD, SEM with EDX, HRTEM and XPS. As novel lubricant additives, the as-prepared B-N-MRG and TiO2B-N-MRG nanomaterials possess appreciable dispersion stability in paraffin oil. Friction and wear characteristics of these nanomaterials were evaluated using four-ball lubricant tester at optimized concentration (0.15% w/v). The observed tribological results show that B/N/B-N doped MRG and TiO2-reinforced MRG exhibit tremendous reduction in MWD (from 0.733 to 0.366 mm) and COF (from 0.0756 to 0.0564) values but load carrying ability gets significantly enhanced from 1078 to 1470N. In addition to this, studied additives exceptionally reduced the steady-state wear rate in the range of 64-98%. SEM and AFM studies revealed that there is some pad-like deposition on the sliding surfaces lubricated with B-N-MRG and TiO2-B-N-MRG which may be the consequence of in situ formed tribofilm preventing metal-metal contact. The XPS analysis of tribofilm formed on the surface lubricated with TiO2-B-N-MRG confirmed the presence of graphitic carbon, boron nitride

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and tribosintered TiO2 nanoparticles. Above results suggest that the synthesized B-N-MRG and TiO2-B-N-MRG nanomaterials are the potential candidates to be developed as SAPS-free antiwear lubricant additives under boundary lubricating conditions. Despite its low thickness, MRGs have improved anti-frictional properties and imparted relatively high wear resistance that makes them attractive materials for various applications in tribology. Conflict of interests The authors declare no competing financial interest. Supporting Information: Experimental details of tribological testing, Raman spectra of nanomaterials, XPS survey scan of MRG and TiO2-B-N-MRG, relative absorbance spectra of nanomaterials, variation of MWD and MWV w.r.t. sliding time of the studied additives, plots of running-in and steady-state wear rates, SEM and AFM images of worn steel surfaces at higher load. Acknowledgement One of the authors VJ is thankful to Head, Department of Chemistry, I.I.T. (BHU) Varanasi, India for providing financial assistance as Teaching Assistantship. Authors express deep sense of gratitude to Prof. Moo Hwan Cho, School of Chemical Engineering, Yeungnam University, Gyeongsan, Republic of Korea for XPS and HRTEM studies. We are thankful to the Head, Department of Metallurgical Engineering, I.I.T. (BHU) Varanasi, India for providing the SEM facilities.

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21. Jaiswal, V.; Kalyani.; Rastogi, R. B.; Kumar, R. Tribological Studies of Some SAPSFree Schiff Bases Derived from 4-Aminoantipyrine and Aromatic Aldehydes and Their Synergistic Interaction with Borate Ester. J. Mater. Chem. A 2014, 2, 1042410434. 22. Li, J.; Xu, X.; Wang, Y.; Ren, T. Tribological Studies on a Novel Borate Ester Containing Benzothiazol-2-yl and Disulfide Groups as Multifunctional Additive. Tribol. Int. 2010, 43, 1048-1053. 23. Gusain, R.; Singh, R.; Sivakumar, K. L. N.; Khatri, O. P. Halogen-Free Imidazolium/Ammonium bis(salicylato) borate Ionic Liquids as High Performance Lubricant Additives. RSC Adv. 2014, 4, 1293-1301. 24. Gusain,

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28. Jaiswal, V.; Rastogi, R. B.; Kumar, R.; Singh, L.; Mandal, K. D. Tribological Studies of Stearic Acid-Modified CaCu2.9Zn0.1Ti4O12 Nanoparticles as Effective Zero SAPS Antiwear Lubricant Additives in Paraffin Oil. J. Mater. Chem. A 2014, 2, 275-286. 29. Hu, Z. S.; Dong, J. X.; Chen, G. X.; He, J. Z. Preparation and Tribological Properties of Nanoparticles Lanthanum Borate. Wear 2000, 243, 43-47. 30. Pu, J.; Wan, S.; Zhao, W.; Mo, Y.; Zhang, X.; Wang, L.; Xue, Q. Preparation and Tribological Study of Functionalized Graphene IL Nanocomposite Ultrathin Lubrication Films on Si Substrates. J. Phys. Chem. C 2011, 115, 13275-13284. 31. Feng, X.; Kwon, S.; Park, J. Y.; Salmeron, M. Superlubric Sliding of Graphene Nanoflakes on Graphene. ACS Nano 2013, 7, 1718-1724. 32. Huang, T.; Xin, Y.; Li, T.; Nutt, S.; Su, C.; Chen, H.; Liu, P.; Lai, Z. Modified Graphene/Polyimide Nanocomposites: Reinforcing and Tribological Effects. ACS Appl. Mater. Interfaces 2013, 5, 4878-4891. 33. Lin, J.; Wang, L.; Chen, G. Modification of Graphene Platelets and their Tribological Properties as a Lubricant Additive. Tribol. Lett. 2011, 41, 209-215. 34. Khare, V.; Pham, M.-Q.; Kumari, N.; Yoon, H.-S.; Kim, C.-S.; Park, J.-I.; Ahn, S.-H. Graphene-Ionic Liquid Based Hybrid Nanomaterials as Novel Lubricant for Low Friction and Wear. ACS Appl. Mater. Interfaces 2013, 5, 4063-4075. 35. Eswaraiah, V.; Sankaranarayanan V.; Ramaprabhu, S. Graphene-Based Engine Oil Nanofluids for Tribological Applications. ACS Appl. Mater. Interfaces 2011, 3, 42214227. 36. Huang, T.; Xin, Y.; Li, T.; Nutt, S.; Su, C.; Chen, H.; Liu, P.; Lai, Z. Modified Graphene/Polyimide Nanocomposites: Reinforcing and Tribological Effects. ACS Appl. Mater. Interfaces 2013, 5, 4878-4891.

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37. Liang, H.; Bu, Y.; Zhang, J.; Cao, Z.; Liang, A. Graphene Oxide Film as Solid Lubricant. ACS Appl. Mater. Interfaces 2013, 5, 6369-6375. 38. Berman, D.; Erdemir, A.; Sumant, A. V. Graphene: A New Emerging Lubricant. Mater. Today 2014, 17, 32-42. 39. Vicarelli, L.; Heerema, S. J.; Dekker, C.; Zandbergen, H. W. Controlling Defects in Graphene for Optimizing the Electrical Properties of Graphene Nanodevices. ACS Nano 2015, 9, 3428-3435. 40. Corato, M. D.; Cocchi, C.; Prezzi, D.; Caldas, M. J.; Molinari, E.; Ruini, A. Optical Properties of Bilayer Graphene Nanoflakes. J. Phys. Chem. C 2014, 118, 2321923225. 41. Balandin, A. A. Thermal Properties of Graphene and Nanostructured Carbon Materials. Nature Mater. 2011, 10, 569-581. 42. Zhu, S.-E.; Li, F.; Wang, G.-W.; Mechanochemistry of Fullerenes and Related Materials. Chem. Soc. Rev. 2013, 42, 7535-7570. 43. Ritter K. A.; Lyding, J. W. The Influence of Edge Structure on the Electronic Properties of Graphene Quantum Dots and Nanoribbons. Nature Mater. 2009, 8, 235242. 44. Yasaei, P.; Kumar, B.; Hantehzadeh, R.; Kayyalha, M.; Baskin, A.; Repnin, N.; Wang, C.; Klie, R. F.; Chen, Y. P.; Král, P.; Amin, S.-K., Chemical Sensing with Switchable Transport Channels in Graphene Grain Boundaries. Nature Comm. 2014, 5, 4911. 45. Benson, J.; Xu, Q.; Wang, P.; Shen, Y.; Sun, L.; Wang, T.; Li, M.; Papakonstantinou, P. Tuning the Catalytic Activity of Graphene Nanosheets for Oxygen Reduction Reaction via Size and Thickness Reduction. ACS Appl. Mater. Interfaces 2014, 6, 19726-19736.

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46. Meng, Y.; Su, F.; Chen, Y. A Novel Nanomaterial of Graphene Oxide Dotted with Ni Nanoparticles Produced by Supercritical CO2-Assisted Deposition for Reducing Friction and Wear. ACS Appl. Mater. Interfaces 2015, 7, 11604-11612. 47. Mungse, H. P.; Khatri, O. P. Chemically Functionalized Reduced Graphene Oxide as a Novel Material for Reduction of Friction and Wear. J. Phys. Chem. C 2014, 118, 14394-14402. 48. Kim, K.-S.; Lee, H.-J.; Lee, C.; Lee, S.-K.; Jang, H.; Ahn, J.-H.; Kim, J.-H.; Lee, H.J. Chemical Vapor Deposition-Grown Graphene: The Thinnest Solid Lubricant. ACS Nano 2011, 5, 5107-5114. 49. How, G. T. S.; Pandikumar, A.; Ming, H. N.; Ngee, L. H. Highly Exposed {001} Facets of Titanium Dioxide Modified with Reduced Graphene Oxide for Dopamine Sensing. Sci. Rep. 2014, 4, 1-8. 50. Jia, Z.; Chen, T.; Wang, J.; Ni, J.; Li, H.; Shao, X. Synthesis, Characterization and Tribological Properties of Cu/Reduced Graphene Oxide Composites. Tribol. Int. 2015, 88, 17-24. 51. Guo, D.; Lu, Y.; Zhao, Y.; Zhang, X. Synthesis and Physicochemical Properties of Graphene/ZrO2 Composite Aerogels. RSC Adv. 2015, 5, 11738-11744. 52. Sabareesh, R. K.; Gobinath, N.; Sajith, V.; Das, S.; Sobhan, C.B. Application of TiO2 Nanoparticles as a Lubricant-Additive for Vapor Compression Refrigeration Systems- An Experimental Investigation. Int. J. Refrig. 2012, 35, 1989-1996. 53. Umrao, S.; Gupta, T. K.; Kumar, S.; Singh, V. K.; Sultania, M. K.; Jung, J. H.; Oh, I.K.; Srivastava, A. Microwave-Assisted Synthesis of Boron and Nitrogen co-doped Reduced Graphene Oxide for the Protection of Electromagnetic Radiation in KuBand. ACS Appl. Mater. Interfaces 2015, 7, 19831-19842.

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54. Kozlova, E. A.; Kozhevnikova, N. S.; Cherepanova, S. V.; Lyubina, T. P.; Gerasimov, E. Y.; Kaichev, V. V.; Vorontsov, A. V.; Tsybulya, S. V.; Rempel, A. A.; Parmon, V. N. Photocatalytic Oxidation of Ethanol Vapors Under Visible Light on CdS–TiO2 Nanocatalyst. J. Photochem. Photobiol. A 2012, 250, 103-109. 55. Jaiswal, V.; Gupta, S. R.; Rastogi, R. B.; Kumar, R.; Singh, V. P.; Evaluation of Antiwear Activity of Substituted Benzoylhydrazones and Their Copper(II) Complexes in Paraffin Oil as Efficient Low SAPS Additives and Their Interactions with the Metal Surface using Density Functional Theory. J. Mater. Chem. A 2015, 3, 50925109. 56. Li, Z. Q.; Lu, C. J.; Xia, Z. P.; Zhou, Y.; Luo, Z. X-ray Diffraction Patterns of Graphite and Turbostratic Carbon. Carbon 2007, 45, 1686-1695. 57. Ferrari, A. C.; Robertson, J. Interpretation of Raman Spectra of Disordered and Amorphous Carbon. Phys. Rev. B 2000, 61, 14095-14107. 58. Barros, E. B.; Demir, N. S.; Filho, A. G. S.; Filho, J. M.; Jorio, A.; Dresselhaus, G.; Dresselhaus, M. S. Raman Spectroscopy of Graphitic Foams. Phys. Rev. B 2005, 71, 165422-165426. 59. Reddy, A.L.M.; Srivastava, A.; Gowda, S.R.; Gullapalli, H.; Dubey, M.; Ajayan, P.M. Synthesis Of Nitrogen-Doped Graphene Films For Lithium Battery Application. ACS Nano 2010, 4, 6337-6342. 60. Han, N.; Cuong, T. V.; Han, M.; Ryu, B. D.; Chandramohan, S.; Park, J. B.; Kang, J. H.; Park, Y.-J.; Ko, K. B.; Kim, H. Y.; Kim, H. K.; Ryu, J. H.; Katharria, Y. S.; Choi, C.-J.; Hong, C.-H. Improved Heat Dissipation in Gallium Nitride Light-Emitting Diodes with Embedded Graphene Oxide Pattern. Nature Comm. 2013, 4, 1452 (1-8). 61. Bourlinos, A. B.; Trivizas, G.; Karakassides, M. A.; Baikousi, M.; Kouloumpis, A.; Gournis, D.; Bakandritsos, A.; Hola, K.; Kozak, O.; Zboril, R.; Papagiannouli, I.;

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Aloukos, P.; Couris, S. Green and Simple Route toward Boron Doped Carbon Dots with Significantly Enhanced Non-Linear Optical Properties. Carbon 2015, 83, 173179. 62. Yan, J.; Zeng, X.; Heide, E. V. D.; Ren, T. The Tribological Performance and Tribochemical Analysis of Novel Borate Esters as Lubricant Additives in Rapeseed Oil. Tribol. Int. 2014, 71, 149-157. 63. Cavdar, B.; Ludema, K. C. Dynamics of Dual Film Formation in Boundary Lubrication of Steels Part I. Functional Nature and Mechanical Properties. Wear 1991, 148, 305-327. 64. Ji, H. B.; Nicholls, M. A.; Norton, P. R.; Kasrai, M.; Capehart, T. W.; Perry, T. A.; Cheng, Y.-T. Zinc Dialkyldithiophosphate Antiwear Films: Dependence on Contact Pressure and Sliding Speed. Wear 2005, 258, 789-799. 65. Shulga, Y. M.; Moravskaya, T. M.; Gurov, S. V.; Chukalin, V. I.; Y. G. Borod'ko. Poverkhnost, 1990, 9, 155-157. 66. Hendrickson, D. N.; Hollander, J. M.; Jolly, W. L. Nitrogen ls electron binding energies. Correlations with molecular orbital calculated nitrogen charges. Inorg. Chem. 1969, 8, 2642-2647. 67. Li, J.; Xu, X.; Wang, Y.; Ren, T. Tribological studies on a novel borate ester containing benzothiazol-2-yl and disulfide groups as multifunctional additive. Tribol. Int. 2010, 43, 1048-1053.

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List of figure caption Figure 1. SEM images of (a) MRG, (b) B-N-MRG and (c) TiO2-B-N-MRG with EDX spectrum Figure 2. TEM and HRTEM images respectively for MRG (a and b), B-N-MRG (c and d) and TiO2-B-N-MRG (e and f) Figure 3. XRD diffraction pattern of MRGs nanomaterials (a) and the highlighted peak with red circle fitted with three different peak (b) Figure 4. Deconvoluted XPS spectra of TiO2-B-N-MRG nanomaterial: (a) C1s core shell spectra, (b) B1s core shell spectra, (c) N1s core shell spectra and (d) Ti2p core shell spectra Figure 5. Variation of mean wear scar diameter for the paraffin oil as a function of increasing additive concentrations at 392N applied load and 60 min duration Figure 6. Variation in mean wear scar diameter and coefficient of friction in the presence of MRGs nanomaterials in paraffin oil. Load: 392N, sliding speed: 1200 rpm, temperature: 75 °C, test duration: 60 min., concentration of MRGs: 0.15 % w/v Figure7. Variation in coefficient of friction as a function of time in the presence of MRGs nanomaterials in paraffin oil. Load: 392N, sliding speed: 1200 rpm, temperature: 75 °C, test duration: 60 min., concentration of MRGs: 0.15 % w/v Figure 8. Variation of mean wear scar diameter with applied load for paraffin oil containing 0.15% w/v of different MRGs nanomaterials for 30 min test duration Figure 9. Variation in mean wear scar diameter and coefficient of friction in the presence of MRGs nanomaterials in paraffin oil. Load: 392N, sliding speed: 600 rpm, temperature: 75 °C, test duration: 60 min., concentration of MRGs: 0.15 % w/v

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Figure10. Variation of frictional torque as a function of step loading and time for different graphene based nanomaterials. sliding speed: 600 rpm, temperature: 75 °C, concentration of MRGs: 0.15 % w/v Figure11. SEM micrographs at different magnifications of the worn steel surface lubricated with different additives (0.15% w/v) in paraffin oil for 60 min test duration at 392 N applied load: (a) Paraffin oil, (b) MRG, (c) B-MRG, (d) N-MRG, (e) B-N-MRG and (f) TiO2-B-NMRG Figure12. 2D and 3D-AFM images of the worn steel surface lubricated with different additives (0.15% w/v) in paraffin oil for 60 min test duration at 392 N applied load: (a) Paraffin oil, (b) MRG, (c) B-MRG, (d) N-MRG, (e) B-N-MRG and (f) TiO2-B-N-MRG Figure 13. Deconvoluted XPS spectra of the tribofilm formed on the steel surface lubricated with TiO2-B-N-MRG nanomaterial under ASTM D5183 test standard: (a) C1s spectra, (b) B1s spectra, (c) N1s spectra, (d) Ti2p spectra, (e) Fe 2p spectra and (f) O1s spectra

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Figures

Figure 1. SEM images of (a) MRG, (b) B-N-MRG and (c) TiO2-B-N-MRG with EDX spectrum

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Figure 2. TEM and HRTEM images respectively for MRG (a and b), B-N-MRG (c and d) and TiO2-B-N-MRG (e and f)

Figure 3. XRD diffraction pattern of MRGs nanomaterials (a) and the highlighted peak with red circle fitted with three different peak (b)

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Figure 4. Deconvoluted XPS spectra of TiO2-B-N-MRG nanomaterial: (a) C1s core shell spectra, (b) B1s core shell spectra, (c) N1s core shell spectra and d) Ti2p core shell spectra

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Figure 5. Variation of mean wear scar diameter for the paraffin oil as a function of increasing additive concentrations at 392N applied load and 60 min duration

Figure 6. Variation in mean wear scar diameter and coefficient of friction in the presence of MRGs nanomaterials in paraffin oil. Load: 392N, sliding speed: 1200 rpm, temperature: 75 °C, test duration: 60 min., concentration of MRGs: 0.15 % w/v

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Figure 7. Variation in coefficient of friction as a function of time in the presence of MRGs nanomaterials in paraffin oil; Load: 392N, sliding speed: 1200 rpm, temperature: 75 °C, test duration: 60 min., concentration of MRGs: 0.15 % w/v

Figure 8. Variation of mean wear scar diameter with applied load for paraffin oil containing 0.15% w/v of different MRGs nanomaterials for 30 min test duration

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Figure 9. Variation in mean wear scar diameter and coefficient of friction in the presence of MRGs nanomaterials in paraffin oil. Load: 392N, sliding speed: 600 rpm, temperature: 75 °C, test duration: 60 min., concentration of MRGs: 0.15 % w/v

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Figure 10. Variation of frictional torque as a function of step loading and time for different graphene based nanomaterials. sliding speed: 600 rpm, temperature: 75 °C, concentration of MRGs: 0.15 % w/v

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Figure 11. SEM micrographs at different magnifications of the worn steel surface lubricated with different additives (0.15% w/v) in paraffin oil for 60 min test duration at 392 N applied load: (a) Paraffin oil, (b) MRG, (c) B-MRG, (d) N-MRG, (e) B-N-MRG and (f) TiO2-B-NMRG

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Figure 12. 2D and 3D-AFM images of the worn steel surface lubricated with different additives (0.15% w/v) in paraffin oil for 60 min test duration at 392 N applied load: (a) Paraffin oil, (b) MRG, (c) B-MRG, (d) N-MRG, (e) B-N-MRG and (f) TiO2-B-N-MRG

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Figure 13. Deconvoluted XPS spectra of the tribofilm formed on the steel surface lubricated with TiO2-B-N-MRG nanomaterial under ASTM D5183 test standard: (a) C1s spectra, (b) B1s spectra, (c) N1s spectra, (d) Ti2p spectra, (e) Fe 2p spectra and (f) O1s spectra

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Table Table 1. Wear rates of paraffin oil in absence and presence of MRG based nanomaterials as antiwear additives at 392N applied load for 90 min test duration

Wear rate (10-4 x mm3/h) RunningSteady-state in 84.48 53.32

Sl. No.

Lubricant additives

1

Paraffin oil

2

MRG

31.09

19.09

3

B-MRG

18.75

09.08

4

N-MRG

13.13

06.14

5

B-N-MRG

05.91

03.02

6

TiO2-B-N-MRG

03.52

00.79

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