Abstract
Hematite (α-Fe2O3) with uniform hexagonal flake morphology has been successfully synthesized using a combination of gelatin as natural template with F127 via hydrothermal method. The resulting hematite was investigated as adsorbent and photocatalyst for removal of ibuprofen as pharmaceutical waste. Hexagonal flake-like hematite was obtained following calcination at 500 °C with the average size was measured at 1–3 µm. Increasing the calcination temperature to 700 °C transformed the uniform hexagonal structure into cubic shape morphology. Hematite also showed high thermal stability with increasing the calcination temperatures; however, the surface area was reduced from 47 m2/g to 9 m2/g. FTIR analysis further confirmed the formation Fe-O-Fe bonds, and the main constituent elements of Fe and O were observed in EDX analysis for all samples. α-Fe2O3 samples have an average adsorption capacity of 55–25.5 mg/g at 12–22% of removal efficiency when used as adsorbent for ibuprofen. The adsorption capacity was reduced as the calcination temperatures increased due to the reduction of available surface area of the hexagonal flakes after transforming into cubes. Photocatalytic degradation of ibuprofen using hematite flakes achieved 50% removal efficiency; meanwhile, combination of adsorption and photocatalytic degradation further removed 80% of ibuprofen in water/hexane mixtures.
Highlights
Hematite has been widely investigated as adsorbent for removal of dye, pharmaceutical compound, heavy metal, and industrial waste [1,2,3,4]
Since green synthesis of hematite requires a high stability of template that promises a high regeneration power, this research aimed to synthesize hematite using a combination of gelatin and F127 as structure directing agents
Iron oxide (Fe2O3-G) with uniform hexagonal flake morphology has been successfully synthesized using a combination of gelatin as a natural template and F127 as a synthetic
Summary
Hematite has been widely investigated as adsorbent for removal of dye, pharmaceutical compound, heavy metal, and industrial waste [1,2,3,4]. The surface area of hematite was reported between 10–90 m2 /g, showing ability as adsorbent in the removal of cephalecin, acetylsalicylic acid, congo red, and heavy metals [2,3]. The hydrophilicity of hematite is reasonably high, beneficial for the adsorption of many organic molecules in water [9]. Hematite was reported to prevent flotation when used as adsorbent for oleate [4]. Antisteroidal agent waste, such as ibuprofen, polluted water and land when discharged from the hospital drainage untreated [11]. The semiconductor property causes hematite to be widely used as photocatalysts, pigments, and gas sensors [8,9,16]
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