1. Introduction

Friction and wear are the most problematic challenges for mechanical systems, resulting in material loss, environmental pollution, and dramatically limiting the reliability, efficiency, and service life [1]. To answer these tribological challenges, advanced new materials, novel technologies, and novel strategies to control the friction and wear are paramount for the reliable and effective use of modern-day equipment [2,3,4,5]. In this pursuit, titanium alloys have been extensively used in aviation, marine, and weapons because of their excellent comprehensive performance, high temperature, high pressure, and corrosion resistance [6]. However, titanium alloys exhibit a high friction coefficient and poor wear resistance because of their high adhesion, low hardness, and low elastic modulus, which limits their engineering applications [7]. To improve the tribological performance of titanium alloys, several surface treatment technologies such as chemical vapor deposition, spraying, and laser processing are widely used [8]. Published research has established that titanium nitride (TiN), titanium aluminum nitride (TiAlN), titanium carbonitride (TiCN), and diamond-like carbon (DLC) films have good friction and wear properties and are employed on metal surfaces to prolong the service life of sliding parts [9,10,11,12]. DLC films have drawn much attention in this quest due to their high hardness, chemical inertness, low friction properties, and low wear [13,14]. For example, Liu et al. deposited DLC films on the surface of a titanium alloy previously implanted with carbon ions by plasma-enhanced chemical vapor deposition (PECVD); for the prepared film, the COF was around 0.1, which was about 1/3 of the reference titanium substrate [15]. In another study, Zhang et al. prepared DLC films with different nest area densities on the Ti–6Al–4V surfaces using magnetron sputtering and laser surface texturing techniques. The results show that DLC films with different dimple area densities affect the tribological properties, with dimple area densities close to 44% having good friction reduction and dimple densities close to 24% having excellent wear resistance [16]. Even though the DLC film had excellent wear resistance, the friction coefficient was still higher than 0.1; to mitigate these problems of DLC films, recently, efforts have been made to fabricate the heterostructures by combining MoS₂ with other two-dimensional materials and DLC coatings [17,18]. Theoretical calculations show that the fabrication of heterostructures offers the possibility of achieving superlubricity because the energy consumption by the friction of the hierarchical structure is an order of magnitude less than that of each component [19]. For example, Zhang et al. achieved superlubricity on the silicon substrate by fabricating MoS₂ and DLC heterostructures, which was attributed to the fact that the fabrication of the heterostructures effectively suppressed the dissipation of energy in the friction process [20]. Zhang et al. prepared MoS₂ and graphite-like heterostructures by magnetron sputtering and PECVD, achieving superlubricity even at high speeds and loads [21]. Sumant et al. realized superlubricity via MoS₂ and nanodiamonds on a Si substrate, where the in situ formation of onion-like carbon nanoscrolls reduced the contact surface and led to incommensurate contact [22]. Sumant et al. obtained a low friction coefficient of 0.018 by graphene + MoS₂ films at the sliding interface in the friction process [23]. Other studies have demonstrated that heterogeneous structures have the potential to reduce friction and wear, providing strong evidence for understanding the superlubricity mechanisms and designing lubricating interfaces [24,25]. However, many studies have shown that the high internal stresses within DLC films make them difficult to deposit directly on titanium alloys and other metal substrates, resulting in films that tend to flake off under experimental conditions [26,27]. The engineering applications with hierarchical structures on the surface of titanium alloys are still challenging [28].

In this study, we fabricated a composite film made of a-C:H film and MoS₂ nanosheets on the surface of titanium alloys using magnetron sputtering and spraying. The tribological behavior of the composite film under different loads was investigated using a reciprocating tribometer. The results show that compared to the reference titanium alloy samples, the Mo-a films reduced friction and wear, achieving a superlubricity state with 0.007, which establishes that Mo-a composite films are useful for lubricating titanium alloy surfaces. Furthermore, we also found that the production of an oriented MoS₂ and graphene-like structure and its structural transformation into a MoS₂ nanoscroll facilitates the achievement of superlubricity. The introduction of the composite films achieved the superlubricity of titanium alloys and provided a strategy for designing superlubricity on metal surfaces.

2. Experimental Methods

2.1. Materials

MoS₂ flakes were purchased from ZhongNuo Advanced Material (Beijing, China) Technology Co., Ltd. Ti targets (>99.99%) were acquired from Sinova New Material (Beijing, China) Technology Co., Ltd.

2.2. The Preparation of a-C:H Film

A high vacuum multi-functional magnetron sputtering ion coating system equipped with argon and methane gas sources was used to deposit composite Ti/TiC/a-C:H films onto a titanium alloy in an argon/methane atmosphere. Before the deposition of the film on the substrate, the surface of the titanium alloy was rubbed with sandpaper of different grit sizes (400#, 800#, 1000#, 1500#, and 2000#) to remove surface oxides and impurities. The polished titanium alloy substrates and silicon wafers (2 × 2 cm²) were then ultrasonically cleaned for 30 min in an ethanol solution. After cleaning, the substrates were mounted on a revolving rack on the vacuum chamber’s sample table. To begin the film deposition process, argon gas was introduced into the vacuum chamber at a flow rate of 17 sccm when the chamber pressure reached 1.0 × 10⁻³ Pa through mechanical and molecular pumps. The substrate was then cleaned for 30 min at a 406 V bias voltage. The overall interlayer film deposition process of the composite film is as follows:

• (1). Titanium layer deposition: The titanium layer was deposited for 30 min at a rate of 120 sccm of argon flow, 100 V of bias voltage, and 2 A of sputtering current.

• (2). Titanium carbide interlayer deposition: First, the argon flow rate was adjusted to 30 sccm for the deposition of the titanium carbide interlayer, and the methane flow rate was increased from 8 sccm to 30 sccm with a gradient of 2 sccm every 3 min.

• (3). a-C:H layer deposition: For the deposition of the a-C:H layer, the sputtering power was turned off, and methane was introduced at the flow rate of 30 sccm, bias voltage 800 V, and was deposited for 120 min.

2.3. The Preparation of MoS₂ + a-C:H Film

For the preparation of the MoS₂ + a-C:H film, 40 mg of MoS₂ powder was added into 5 mL of ethanol (concentration of 8 mg/mL) and ultrasonicated for 30 min. Then, 1 mL of the as-prepared MoS₂ solution was sprayed on the surface of the 2 × 2 cm² a-C:H film. Thus, the Mo-a film was obtained when complete ethanol solvent was evaporated under light-assisted irradiation. For comparative analysis, 1 mL of the MoS₂ dispersion was sprayed on the titanium alloy substrate to fabricate a MoS₂ film.

2.4. Structure Characterizations

The microstructure, surface morphology, and elemental distribution of the as-prepared films were investigated by scanning electron microscopy (Japan Electronics Company, JSM-5601LV, Toyama, Japan). The cross-section of a-C:H film on a Si substrate was observed by field emission scanning electron microscopy (Japan Electronics Company, JSM-6701F, Toyama, Japan) at 5.0 kV. The counterpart ball’s wear debris nanostructure was investigated with field emission electron microscopy (FEI company, TF20, Hillsboro, OR, USA). The wear tracks and scars were investigated by Raman spectroscopy at a laser wavelength of 532 nm with a LabRam HR800 spectrometer (HORIBA Jobin Yvon S.A.S, LabRAM HR Evolution, Palaiseau, France). The hardness, elastic modulus, and elastic recovery rate of a-C:H film were measured by the Hit 300 nanoindentation tester. To investigate the anti-wear performance of the Mo-a film, MoS₂ samples, a-C:H samples, and titanium alloy samples under different loads were characterized with a MAX 3D surface profiler (KLA-Tencor, MicroXAM-800, Milpitas, CA, USA) after the friction tests.

2.5. Tribological Testing

In linear reciprocating sliding mode, friction tests were conducted using a ball-on-disk tribometer (Anton Paar, CSM TBR³, Buchs, Switzerland) with normal loads of 1, 3, 5, 7, 9, and 11 N, and 6 mm diameter steel balls were used as a sliding counterpart. Before each experiment, high-purity helium was introduced, and the experiment was started once the relative humidity fell to 5%. The reciprocating frequency and the amplitude for each test were set to 5 Hz and 5 mm, respectively. All of the friction tests were repeated three times to ensure the stability and repeatability of the test results.

2.6. Nanoindentation Tests

The modulus of elasticity R was calculated using Equation (1), where d _max is the maximum displacement at maximum load, and d _res is the residual displacement after unloading.

R = (d _max − d _res)/d _max × 100% (1)

2.7. Wear Rate Calculation

In addition, the wear rates were calculated according to the Equation (2):

W = V/F × L(2)

3. Results and Discussion

3.1. Structural and Composition Analysis

Figure 1a shows the schematic of the ball-on-disk reciprocating friction experiment setup, which was used to study the friction of the Mo-a film and steel counter ball in a helium atmosphere. The mechanical properties of the a-C:H films are displayed in Figure 1b; the elastic modulus, hardness, and elastic recovery of the a-C:H films were 131.8 GPa, 11.3 GPa, and 62%, respectively, which shows that a-C:H films had outstanding mechanical properties. Figure 1c shows the Raman spectrum of the a-C:H film, where the D peak and G peak of the a-C:H film appeared at 1407 and 1539 cm⁻¹, corresponding to the respiratory vibration mode of the aromatic ring and the vibration stretching mode of the sp² site pair in the aromatic or alkene chain, respectively [29,30]. The intensity variations in the characteristic peaks of the a-C:H films provide important information for probing the structural changes at the friction interface. The intensity ratio of the D and G peaks (I_D/I_G) of the a-C:H film was 0.58. Figure 1d shows that there was only a weak G peak and no D peak in the Raman spectrum of the Mo-a composite film, which indicates that the a-C:H film was almost completely covered by the MoS₂ film. Moreover, two narrow and sharp peaks near 378 and 404 cm⁻¹ were the E¹_g2 and the A1g signals, corresponding to MoS₂. E¹_g2 is the signal generated by the reverse vibration of two S atoms in the fundamental plane for one Mo atom, while A_1g is caused by the out-of-plane or vertical vibration of the S atom in the opposite direction [31]. The surface morphology of the Mo-a film sample is shown in Figure 1e, with a large amount of MoS₂ sheets distributed on the surface of the a-C:H film. Figure 1f shows the distribution of the C, S, Mo, and O elements in the surface of the a-C:H film. It can be seen that there were a large number of Mo and S elements distributed on the surface of the a-C:H film, which also demonstrates that the a-C:H film surface was entirely covered by MoS₂. Figure 1g shows a cross-sectional image of the a-C:H film. From the cross-section of the film, it can be seen that the multilayer film structure comprised the Ti layer, the TiC interlayer, and the a-C:H layer, with an overall thickness of 2.98 μm with a clear boundary between each layer. The thickness of the bottom Ti layer was approximately 1.16 μm, the middle transition layer TiC was approximately 0.22 μm, and the top a-C:H layer was about 1.60 μm. Figure 1h shows the elemental mapping of the a-C:H film, where it can be seen that the cross-sectional region had a large amount of Ti and C elements.

3.2. Tribological Performance Analysis

The tribological performances of the as-prepared a-C:H film, titanium alloy, MoS₂ coating, and Mo-a film relative to a steel ball sliding under a 5 N load in a helium environment are shown in Figure 2a. It can be seen that the friction coefficient of the steel ball sliding on the reference titanium alloy was 0.371, as shown in the inset of Figure 2a. This COF is very high, possibly due to the evaluation of the wear debris. After spraying the MoS₂ solution onto the titanium alloy substrate, the COF dropped to 0.033, which is due to the layered structure of the MoS₂. Once the load was applied to the MoS₂ film, the nanosheets of the MoS₂ were distributed on the sliding track due to the layered structure and easy-to-shear ability of the MoS₂, which provided extra protection to the substrate. For the a-C:H film on the titanium alloy substrate, the COF dropped significantly to 0.056, which was also much better than the reference titanium alloy substrate and the MoS₂ film. Among all samples, superlubricity (COF~0.007) was achieved for the Mo-a film after 500 s of running-in. This superlubricity is triggered by the formation of the transfer film on the counter surface, which transitioned the initial high resistance steel-to-a-C:H contact to super low resistance steel-to-transfer film contact. Furthermore, the Mo-a film was tested at 5 N, 7 N, and 9 N loads to investigate the Mo-a film’s friction coefficient and standard error tribological behavior, as shown in Figure 2b. The COF of Mo-a was still in the ultralow regimes of ~0.007, 0.008, and 0.007 at 5 N, 7 N, and 9 N, respectively. The primary reason behind this remarkable friction reduction to the ultralow regimes is due to the transition of disordered MoS₂ to ordered structures and the formation of incommensurate contact with a-C:H surfaces, as verified elsewhere [16,32].

The anti-wear performance of the as-prepared films was investigated by calculating the wear rate, as shown in Figure 2c. It can be seen that the wear rate of the Mo-a composite film and a-C:H film was lower than that of the reference titanium alloy substrate. The wear rate of the titanium alloy substrate was 1.27 × 10⁻⁴ mm³/N⁻¹·m⁻¹, and the a-C:H film was 2.8 × 10⁻⁷ mm³/N⁻¹·m⁻¹, which means that the deposition of the a-C:H film reduced the wear rate by 1/453. Figure 2d shows the wear rate of the Mo-a composite film under different loads. The maximum wear rate of the composite film was 1.01 × 10⁻³ mm³/N⁻¹·m⁻¹ at a load of 1 N. The lowest wear rate of 3.84 × 10⁻⁵ mm³/N⁻¹·m⁻¹ was obtained at a load of 9 N.

3.3. Friction Reduction Mechanism Analysis

To fully understand the friction reduction mechanism, the relationship between the structural and chemical changes, and their role in the friction reduction at the sliding interface, Raman spectrometry was used. Figure 3 shows the Raman spectra of the wear scars and wear traces for the Mo-a films under different loads. Two characteristic peaks of MoS₂ around 390 and 410 cm⁻¹ in the wear scars of different loads were E¹_2g and A_1g [33]. These obvious peaks indicate that the MoS₂ component of the Mo-a films was successfully transferred to the counterpart balls. In the friction process, the MoS₂ transfer film on the counterpart balls gradually degraded as the load increased, as shown by the decreasing intensity of the characteristic peaks of MoS₂. As the experimental load exceeded 5 N, D and G peaks of the a-C:H film near 1370 and 1600 cm⁻¹ appeared, which corresponded to the MoS₂ and carbon, which implies that the material that is transferred to the counter body in the form of a transfer film is composed of MoS₂ and carbon [34]. However, in the wear scars of the 1 N and 3 N loads, no D peak and G peak were detected, which implies that at low loads, the MoS₂ transfer film is not removed in large quantities, thus avoiding direct contact between the counterpart balls and the a-C:H film at the sliding interface. When the applied load exceeded 5 N, the D and G peaks detected in the wear scars completely differed from the Raman spectra of the a-C:H film, where the D peak of the wear scar appeared split, and the G peak shifted to a higher value. This splitting of the D peak and the shift in the G peak to a higher wave number indicates the graphitization of the a-C:H film [35]. This graphitization degree becomes more severe with the increase in load, implying that higher loads intensify the graphitization process. As mentioned in earlier studies, under high contact pressure, the main friction reduction mechanism in a-C:H films is the formation of graphite-like clusters of surface carbon layers at the sliding interface [36]. Research also shows that the high contact pressure leads to the decomposition of MoS₂ into Mo and S, which is favorable to carbon transformation and results in low friction [1].

Furthermore, the intensity variations in the D peak and G peak I_D/I_G also provide important information for the evolution of the carbon film structure. I_D/I_G values were obtained for 1, 3, 5, 7, 9, and 11 N loads using peak fitting, which were 0.58, 0.56, 0.59, 0.58, 0.59, and 0.50, respectively. From the values of the I_D/I_G of the wear tracks at different loads, it can be inferred that no significant structural evolution occurred in the a-C:H films.

As for the MoS₂ film, achieving single superlubricity with the MoS₂-flakes alone in a helium atmosphere is difficult. Furthermore, the I_D/I_G values of the a-C:H film at low loads of 1 N, 3 N, and 5 N were difficult to measure because the intensity of the D and G peaks in the Raman spectra was very weak. However, the I_D/I_G values in wear scar under 7 N, 9 N, and 11 N loads were 0.95, 0.93, and 0.9, respectively. The I_D/I_G ratio of the wear scars had a higher value at high loads than the value of I_D/I_G for wear traces, which indicates that the a-C:H film transferred to the ball is graphitized compared to the a-C:H film on the wear traces. The Raman spectra results of the wear scars are consistent with those of the previously published studies [37]. The I_D/I_G change can reflect the changes in the sp³ content in the a-C:H films. An increase in the graphitization implies a decreased sp³ carbon bond content [38].

Meanwhile, the blue shift of the G peak also indicates the transition of the sp³ carbon structure to a graphite-like carbon structure during the friction process and reflects the increased graphitization process [39]. Meanwhile, the two weak characteristic peaks of MoS₂ were only detected on weak tracks with a 5 N load; however, no characteristic peaks were detected in other wear tracks. Thus, the effective friction reduction of the Mo-a film material system can be attributed to its conversion of the high-resistance steel and composite contact into super low resistance MoS₂ and a-C:H film contact.

Furthermore, the structural evolution of the wear debris of the Mo-a film was investigated with transmission electron microscopy (TEM). The TEM image of representative wear debris at the 5 N load is shown in Figure 4. Figure 4a shows the two main core areas of wear debris where the I region is enriched with highly ordered nanosheets of MoS₂ with an interlayer distance of 0.63 nm. In contrast, the II region is filled with curved graphene with an interlayer distance of 0.33 nm. In fact, during the sliding process, superlubricity can be triggered by many factors such as the applied load, the environment, shear stress, and the frictional chemistry of the contact area [40,41]. It has also been shown that the composite films of MoS₂ produced an ultra-low friction phenomenon, which was attributed to the fact that the sliding direction was related to the friction-induced direction parallel to the shear plane of the lamellar structure [42]. Previous studies have shown that frictional stresses at the sliding interface cause structural transformations in the related materials of the friction pairs [1]. Thus, frictional stresses and tribochemical reactions accelerate the transformation of the amorphous carbon film into a graphene-like structure, which is consistent with the Raman characterization results of the wear scar in our work. Figure 4c shows the transformation of MoS₂ nanosheets into nanoscroll structures during stress-induced friction. The production of MoS₂ nanoscrolls significantly reduces the contact area in the contact zone. It demonstrates that contact stress is the main cause of the structural transformation of amorphous carbon films and MoS₂ nanosheets. Based on the above analysis, the superlubricity-achieving mechanism evolves in three broad stages as follows. (1) Amorphous carbon forms graphene under the action of frictional heat and contact stress, as demonstrated by previous studies [43]. At the same time, it has been shown that the formation of heterojunctions facilitates the reduction in contact areas and the elimination of strong carbon–carbon bonds across interfaces [44]. (2) The formation of MoS₂/graphene heterojunctions reduces the release of frictional energy. (3) The formation of nanoscroll structures reduces the contact area and suppresses energy dissipation.

Figure 5 shows a schematic of the ultra-low friction mechanisms of the steel and Mo-a nanocomposites. When the composite films were subjected to a 5 N load, the coating material was removed and transferred to the surface of the counter body due to several phenomena such as the easy-to-shear ability of MoS₂, alteration of the a-C:H films into graphene-like lamellar structures, and the transformation of MoS₂ nanosheets into MoS₂ nanoscroll structures under high contact shear stress and frictional heat during the friction processes as verified with TEM and Raman characterization. Thus, this achievement of superlubricity can be attributed to the frictional heterojunction interface established by the graphene-like structure and the MoS₂ nanoscrolls, which provides incommensurate contact at the friction interface and remarkably reduces the friction to superlubric regimes.

4. Conclusions

In this work, MoS₂, a-C:H, and Mo-a films were prepared on titanium alloy substrates by spraying and magnetron sputtering and investigated with reciprocating pin disk tribometer and high-resolution characterization techniques. The friction test results show that the Mo-a sample achieved superlubricity with a super low COF of ~0.007 on the titanium alloy substrates, which was remarkably lower than the a-C:H film (µ-0.056), MoS₂ film (µ-0.033), and titanium alloy (µ-0.371) in a He atmosphere. In addition, the fabrication of a-C:H film on the surface of the titanium alloy resulted in a reduction in the wear rate of three orders of magnitude compared to the titanium alloy substrates. It was verified by TEM that the MoS₂ and a-C:H films undergo structural evolution, with the MoS₂ nanosheets transforming into nanoscroll structures and the amorphous a-C:H transforming into layered graphene. The formation of highly ordered MoS₂ nanosheets and graphene heterojunctions resulted in an extremely low state of bond breakage and generation during friction. At the same time, the formation of the MoS₂ nanoscroll structure greatly reduced the frictional contact interface and synergy of the MoS₂ nanoscroll and graphene, which triggered favorable conditions for the achievement of the superlubricity and remarkable wear reduction rate for the Mo-a composite film.

Footnotes

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Figure 1. (a) Illustration of the composite film material composition and friction test. (b) The mechanical properties of the prepared a−C:H film. (c) Raman spectrum of the as-deposited a−C:H film. (d) Raman spectrum of the as−deposited Mo-a films. (e) The surface SEM image of the Mo-a films. (f) The local distribution of the Mo, S, C, and O elements on the surface of the Si substrate. (g) The cross-sectional SEM image of the a−C:H film. (h) The cross-sectional elemental mapping of the a−C:H film.

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Figure 2. (a) Friction coefficient curves for the a−C:H film, MoS2 film, Mo−a films, and titanium alloys under a 5 N load. (b) The average coefficient of friction and standard error of Mo−a films under different loads. (c) The rate of wear of different samples. (d) The wear rate of Mo−a films under different loads.

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Figure 3. Raman spectrum of the wear scar and wear trace in the central region obtained at 1, 3, 5, 9, and 11 N loads.

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Figure 4. TEM image of the debris in the wear scar after the friction test under a 5 N load. (a,b) The wear debris consisted of layered MoS2 and curved graphene, I is layered MoS2, and II is curved graphene. (c,d) The wear debris consisted of MoS2 nanotubes.

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Figure 5. The ultra-low friction mechanism of steel-Mo-a films.

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