IntroductionMolybdenum disulfide (M

IntroductionMolybdenum disulfide (MoS2), a two-dimensional layeredtransition-metal dichalcogenide, has attracted extensive interestdue to its potential in various applications ranging from elec-tronic devices and sensors to catalysts [1–3]. Recent studies showthat single-layered MoS2is a flexible and strong sheet with ahigh Young’s modulus of 270–330 GPa and breaking strength of16–30 GPa [4]. These excellent mechanical properties of MoS2makeit as a promising reinforcing filler for polymeric composites [5].Recently, we demonstrated that, with appropriate surface function-alization, single-layered MoS2exhibited high reinforcing efficiencyfor rubber, which is comparable to that possessed by graphene [6].Natural rubber (NR), one of the most important biosynthesizedpolymers, is widely used for various applications [7–9]. Elastomericmaterial based on NR generally needs to be reinforced with fillerssuch as carbon black (CB), silica, and clays, because its mechani-cal properties especially its low modulus are inadequate for manyapplications [10–12]. Silica has been widely employed as rein-forcement for rubbers, which can greatly improve the overallperformances of the rubber composites [13–16]. Unfortunately,since silica surface bears abundant silanol groups and exhibits highpolarity, it has poor compatibility with non-polar rubbers such as NR.
As a result, silica tends to form severe aggregationin rubber matrix and has poor interfacial interaction with rub-ber macromolecules [18,19]. Therefore, the improvement of silicadispersion is critical in developing high-performance silica-filledelastomeric materials. Many methods such as addition of silanesand in situ generation of silica particles using sol–gel methods havebeen developed to improve the dispersion of silica [20–22]. In addi-tion, incorporation of the hybridized fillers has been shown to beeffective in improving filler dispersion. For example, previous study[23,24] showed that the dispersion of carbon black was improved inthe presence of 2-D clay sheets in epoxidized natural rubber. In suchcomposites, carbon black and nanoclay could form a “nanounit”, inwhich a carbon structural aggregate was positioned between twoclay tactoids, resulting in improvements in the dynamic mechan-ical and tensile properties of the final composite materials [23].Zhang added the hybrid fillers consisting of modified kaolinite andprecipitated silica into styrene-butadiene rubber (SBR), the kaolin-ite sheets were covered by silica particles, improving the thermalstabilities of the SBR composites [24]. However, the use of clay inhybrid fillers requires surface treatment in order to achieve mono-layer dispersion of clay in the rubber matrix.