Abstract
Carbon nanotubes (CNTs), the one-dimensional allotropes of carbon, have attracted noteworthy research interest since their discovery in 1991 owing to their large aspect ratio, low mass density, and unique chemical, physical, and electronic properties that provide exciting possibilities for nanoscale applications. Nonetheless, two major issues should be considered when working with this sort of nanomaterial: their strong agglomerating tendency, since they are typically present as bundles or ropes of nanotubes, and the metallic impurities and carbonaceous fragments that go along with the CNTs. The successful utilization of CNTs in a wide variety of applications—in particular, in the field of polymer composites—depends on their uniform dispersion and the development of a strong chemical interaction with the polymeric matrix. To achieve these aims, chemical functionalization of their sidewalls and tips is required. In this article, a brief overview of the different approaches for CNT modification using polymers is provided, focusing on the covalent functionalization via “grafting to” or “grafting from” strategies. The characteristics and advantages of each approach are thoroughly discussed, including a few typical and recent examples. Moreover, applications of polymer-grafted CNTs as biosensors, membranes, energy storage substances, and EMI shielding are briefly described. Finally, future viewpoints in this vibrant research area are proposed.
Highlights
Carbon nanotubes (CNTs) are 1D carbon-based nanomaterials discovered by Iijima in 1991, which present high length to diameter ratio (>1000), great flexibility, low density (~1.9 g/cm3 ) and outstanding electrical mechanical, and thermal characteristics [1,2], being ideal candidates for a wide range of applications including the development of multifunctional nanocomposites [3]
CNTs are attractive for many disciplines ranging from chemistry, physics, and biology to material science as a result of their exceptional characteristics and far-ranging applications in diverse fields including optoelectronics, biomedical, and biotechnology
All of them result in a nanocomposite with increased solubility, high interaction between polymer and CNT, and effective CNT debundling
Summary
Carbon nanotubes (CNTs) are 1D carbon-based nanomaterials discovered by Iijima in 1991, which present high length to diameter ratio (>1000), great flexibility, low density (~1.9 g/cm3 ) and outstanding electrical mechanical, and thermal characteristics [1,2], being ideal candidates for a wide range of applications including the development of multifunctional nanocomposites [3]. (3) those comprising concentric cylinders (several SWCNTs), with diameters in the range of 3–40 nm, named as multiwalled carbon nanotubes (MWCNTs, Figure 1C,D)) These two kinds of CNTs can be synthesized via diverse ways [6], namely chemical vapour deposition (CVD) from hydrocarbons, arcdischarge and laser ablation processes. Future viewpoints in this vibrant research area will be provided
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