Abstract
Electrospinning techniques have become an efficient way to produce continuous and porous carbon nanofibers. In view of CO2 capture as one of the important works for alleviating global warming, this study intended to synthesize polyacrylonitrile (PAN)-based activated carbon nanofibers (ACNFs) using electrospinning processes for CO2 capture. Different structures of PAN-based ACNFs were prepared, including solid, hollow, and porous nanofibers, where poly(methyl methacrylate) (PMMA) was selected as the sacrificing core or pore generator. The results showed that the PMMA could be removed successfully at a carbonization temperature of 900 °C, forming the hollow or porous ACNFs. The diameters of the ACNFs ranged from 500 to 900 nm, and the shell thickness of the hollow ACNFs was approximately 70–110 nm. The solid ACNFs and hollow ACNFs were microporous materials, while the porous ACNFs were characterized by hierarchical pore structures. The hollow ACNFs and porous ACNFs possessed higher specific surface areas than that of the solid ACNFs, while the solid ACNFs exhibited the highest microporosity (94%). The CO2 adsorption capacity on the ACNFs was highly dependent on the ratio of V<0.7 nm to Vt, the ratio of Vmi to Vt, and the N-containing functional groups. The CO2 adsorption breakthrough curves could be curve-fitted well with the Yoon and Nelson model. Furthermore, the 10 cyclic tests demonstrated that the ACNFs are promising adsorbents.
Highlights
Carbon fibers are of great significance in scientific and technological applications because of their high specific surface areas, high surface area to volume ratios, easy functionalization, superior mechanical properties, outstanding flexibility, etc., when the carbon fibers are reduced to nanoscale
Compared with other methods, electrospinning is acknowledged as a simple, inexpensive, and efficient process to draw out polymers into continuous fibers with diameters ranging from submicrons to nanometers [3,13]
A fibrous structure is stabilized above a minimum concentration, but the fiber diameter increases with molecular weight and concentration [15]
Summary
Carbon fibers are of great significance in scientific and technological applications because of their high specific surface areas, high surface area to volume ratios, easy functionalization, superior mechanical properties, outstanding flexibility, etc., when the carbon fibers are reduced to nanoscale. These superior properties make the carbon nanofibers show excellent performances in several applications (e.g., gas adsorption, gas storage, filter media, sensors, drug delivery, tissue engineering, protective clothing, etc.) [1,2,3]. The intermolecular entanglements play an important role in stabilizing the fibrous structure [18]
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