Polysulfone metal-activated carbon magnetic nanocomposites with enhanced CO 2 capture.
Muhammad NisarPascal S ThueMyriam B MaghousJulian GeshevEder Claudio LimaSandra EinloftPublished in: RSC advances (2020)
In the present study, polysulfone (PSF)-activated carbon nanocomposites were synthesized by a melt mixing technique. Here, 2 wt% activated carbon (CA, CA-Ni, and CA-Co) was used as filler, and effects on thermal, mechanical, magnetic, morphological, and carbon dioxide capture properties were studied. The pyrolysis of wood sawdust produced carbon materials activated by Co and/or Ni salt. The thermal degradation and the amount of metal in the carbon materials were investigated by thermogravimetric analysis. The maximum degradation temperature showed an improvement of up to 3 °C, while the initial degradation temperature decreased up to 4 °C with the addition of metal-activated carbons. The values of T g estimated by differential scanning calorimetry appear to be practically identical for pure PSF and its nanocomposites. The elasticity modulus of the nanocomposite shows an enhancement of 17% concerning the neat PSF. The water contact angle showed a decrease with the incorporation of the fillers, indicating the hydrophilic nature of the composite. The carbon dioxide sorption capacity of the nanocomposite showed an enhancement of almost 10% in contrast to neat PSF. Ferromagnetic behavior of the thermoplastic nanocomposite was observed with the introduction of 2.0 wt% metal-carbonized filler. The exceptional magnetic properties, for a thermoplastic material such as polysulfone, make it promising for various industrial applications.
Keyphrases
- carbon dioxide
- reduced graphene oxide
- carbon nanotubes
- visible light
- molecularly imprinted
- hyaluronic acid
- solid phase extraction
- gold nanoparticles
- sewage sludge
- quantum dots
- high resolution
- magnetic resonance
- protein kinase
- computed tomography
- liquid chromatography
- magnetic resonance imaging
- risk assessment
- room temperature
- simultaneous determination
- ionic liquid
- organic matter