Abstract

Graphene oxide (GO)–gelatin (G) aerogels were synthesized by covalent and noncovalent methods, changing on the synthesis the GO:G ratio and the pH of the GO suspension, evaluating the physical, chemical, and functional properties of these materials. Comparatively, low GO:G ratios with alkali GO suspension promoted GO–G interactions for covalent aerogels. In contrast, high GO:G ratios under acidic conditions promoted noncovalent interactions. Scanning electron microscopy showed heterogeneous structures with pore sizes of 53.26 ± 25.53 µm and 25.31 ± 10.38 µm for covalent and noncovalent aerogels, respectively. The synthesis method did not influence the surface charge; however, differences were depending on the GO content and their chemical activation, shifting from 15.63 ± 0.55 mV to − 20.53 ± 1.07 mV. Noncovalent aerogels presented higher absorption ratios in phosphate-buffered saline (PBS) solution (35.5 ± 2.4 gPBS/gaerogel–49.6 ± 3.8 gPBS/gaerogel) than covalent aerogels. Therefore, due to these properties, noncovalent aerogels could be more useful than covalent aerogels for absorption potential applications, as biomedicine or water-treatment, where the promotion of surface interactions and high absorption capability is desired.