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Beilstein J. Nanotechnol. 2018, 9, 508–519, doi:10.3762/bjnano.9.49
Figure 1: Digital image of (a) CNF/PVA/GO aerogel with dimensions of 1.6 × 1.7 cm; (b) CNF/PVA/GO carbon aero...
Figure 2: (a), (b), and (d) are SEM images of the inner part of the super-hydrophobic CNF/PVA/GO carbon aerog...
Figure 3: FTIR spectra of the (a) CNFs, (b) PVA, (c) GO, (d) rGO, (e) CNF/PVA/GO aerogel, and (f) CNF/PVA/GO ...
Figure 4: Raman images of the (a) CNFs, (b) PVA, (c) GO, (d) rGO, and (e) CNF/PVA/GO aerogels and the (f) CNF...
Figure 5: X-ray photoelectron spectrometry spectra and deconvolution of (a) survey scans, and C 1s high-resol...
Figure 6: Thermogravimetric analysis (TGA) curves of the CNFs, pure PVA, GO, CNF/PVA/GO aerogel and the CNF/P...
Figure 7: Contact angle of CNF/PVA/GO carbon aerogels.
Figure 8: Removal of soybean oil (dyed with Sudan red) from the water surface using carbon aerogel.
Figure 9: Photographs showing the recycling process of CNF/PVA/GO carbon aerogels via combustion.
Figure 10: Recycling performance of CNF/PVA/GO carbon aerogels for absorption of soybean oil by absorption/com...
Figure 11: Absorption capacity of CNF/PVA/GO carbon aerogels.
Figure 12: Schematic showing the synthetic steps for preparing super-hydrophobic CNF/PVA/GO carbon aerogel.