Abstract
Of late, the demand for new CO2 adsorbents with high adsorption capacity and stability is growing very fast. Nanofibrous adsorbents are potential materials for such application with most attempts made on carbon nanofibers. In this study, a series of electrospun nanofibrous adsorbents containing amines were prepared using a 3-stage promising approach and tested comparatively for CO2 capture. The preparation of adsorbents involved electrospinning of syndiotactic polypropylene (s-PP) solution, radiation-induced grafting (RIG) of glycidyl methacrylate (GMA) onto electrospun nanofibers, and functionalization of poly-GMA grafted s-PP nanofibrous mats with different amines, including ethanolamine (EA) diethylamine (DEA) and triethylamine (TEA). The effect of different amination parameters: namely, amine concentration, reaction time, temperature, and degree of grafting (DG) on the degree of amination (DA), was evaluated. The nanofibrous mats containing amine were tested for CO2 adsorption in a fixed bed column operated under various parameters such as amine density, amine type, initial CO2 concentration and temperature. The adsorbents recorded CO2 adsorption capacities of 2.87, 2.06 and 0.94 mmol/g for EA-, DEA- and TEA-containing adsorbents, respectively, at 30° C using initial CO2 concentration of 15%. This was coupled with the same order of high amine efficiency of 75, 57, and 31%. Results demonstrated that the nanofibrous adsorbent containing amine had strong potential for CO2 capture application.
Highlights
Nowadays, fossil fuels are the primary source for coping with high energy demand around the world
Independent parameters of the electrospinning process including applied voltage, needle tip to collector distance (TCD) and flow rate were varied based on the combinations offered by BoxBehnken design (BBD) of RSM, as reported previously (Abbasi et al, 2018)
The degree of amination (DA) from different amines was found to be dependent on parameters such as degree of grafting (DG), temperature, time and amine concentration
Summary
Fossil fuels are the primary source for coping with high energy demand around the world. This has led to a large amount of carbon dioxide (CO2) being released into the atmosphere. The most commonly used technique for CO2 capture is liquid amine absorption, known as amine scrubbing This technique has some limitations, including high energy demand, amine decomposition during regeneration and equipment corrosion (Xiao et al, 2016). Even though solid-amine based adsorbents suffer from high energy demand during the regeneration process (Hicks et al, 2008), using a non-aqueous process for the adsorption and desorption is one of their advantages over liquid amine absorption
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