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Polymer Nanocomposite Materials


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nanotubes (HNTs)Nickel nanostrands (NiNs)Aluminum oxide nanofibers (Nafen) Nano-silica (n-silica)Nano-alumina (n-Al2O3)Nano-silver (n-Ag)Nano-titanium dioxide (n-TiO2)Nano-silicon carbide (n-SiC)Nano-zinc oxide (n-ZnO)POSS

      1.3.1 One-Dimensional Nanofillers

      1.3.2 Two-Dimensional Nanofillers

      Two-dimensional fillers are the materials with two dimensions less than 100 nm, and they are mostly in the form of rods [14]. The typical two-dimensional nanomaterials are carbon nanofibers (CNFs), carbon nanotubes (CNTs), halloysite nanotubes (HNTs), nickel nanostrands (NiNS), and aluminum oxide nanofibers (Nafen). In addition, the most common two-dimensional nanofillers in PNCs are nanotubes [34], plant fibers [35–39], nanowires [40], carbon fibers [41–44], oxides [45–55], graphene [56, 57], molybdenum disulfide (MoS2) [58], and hexagon boron nitride (h-BN) [59]. Compared with one- and three-dimensional fillers, two-dimensional fillers have better flame retardancy and striped characteristic, resulting in wide applications in the fields of catalysis, electronics, optics, sensing, and energy [3, 26, 60–62].

      1.3.3 Three-Dimensional Nanofillers

      Three-dimensional nanofillers are nanomaterials with three dimensions on the nanometer scale, so they are mostly spherical or cube-shaped [63], which is also commonly referred to zero-dimensional particles. The most common three-dimensional fillers are polyhedral oligomeric silsesquioxane (POSS), nanosilicon, nanometal particles, nanometal oxides, and quantum dots (QDs) [33, 64]. Among them, metals and metal oxide nanoparticles have the advantages of high stability, catalytic activity, and easy preparation, and they are often used in the fields of catalysis [65], purification [66–69], coatings [70–74], and biological fields [75, 76], together with various polymers. One-, two-, and three-dimensional nanofillers all have various special properties, and will ultimately promote the remarkable performance of PNCs by loading in compatible polymers.

Significant properties of polymer nanocomposites

      For example, most polymers don't possess conductivity except some conducting polymers, which is due to the covalent bonding of polymers and the lack of electron channels or ion migration. Interestingly, new PNCs formed by adding conductive nanofillers to insulating polymers exhibit many electrical properties. As early as 1994, Ajayan et al. used CNTs as reinforcement materials to prepare PNCs [77]. Since then, there have been a lot of researches on using CNTs as fillers to improve the electrical properties of PNCs. Only a small volume fraction of such fillers is needed to improve the electrical properties of polymers by several orders of magnitude effectively [78].

Technique Suitable filler Suitable matrix Solvent Controlling factors
Ultrasonication-assisted solution mixing All types Liquid or viscous monomers or oligomers of thermosets Required Sonication power and time
Shear mixing Nanosheets Liquid or viscous monomers or oligomers of thermosets Required Shapes of the rotor blades, rotating speed and time
Three roll milling Nanosheets and nanotubes Liquid or viscous monomers or oligomers of thermosets Not required Speed of roller, gap between adjacent roller
Ball milling All types Liquid or solid thermoplastics and thermosets Not required Time of milling, ball size, rotating speed, ball/nanofiller ratio
Double-screw extrusion All types Solid thermoplastics Not required Processing temperature, screw configuration, rotation speed
In situ synthesis All types Liquid or viscous monomers or oligomers of thermosets Required Chemical reaction conditions, temperature, condensation