Ecotoxicidade de nanocatalisadores de óxidos de ferro, produzidos a partir da drenagem ácida de mina, quando submetidos à ação de ozônio em meio aquoso / Ecotoxicity of iron oxide nanocatalysts, produced from acid mine drainage, when submitted to the action of ozone in aqueous medium

RESUMO Óxidos de ferro recuperados da drenagem ácida de minas representam uma matéria-prima potencial para a produção de baixo custo de nanogoetita ou nanohematita, com grau de pureza adequado para o seu uso como catalisador em processos de tratamento de efluentes líquidos com ozônio. Assim, a toxicidade das nanopartículas de ferro precisa ser determinada para prever seu impacto no meio ambiente, antes e depois de terem sido utilizadas nesses processos. Nesse contexto, o objetivo deste estudo foi avaliar a toxicidade de nanogoetita e nanohematita produzidas a partir da drenagem ácida de minas bem como comparar os resultados com hematita sintética de alta pureza. A nanogoetita foi obtida da drenagem ácida de minas e, após seu tratamento térmico a 450°C, produziu nanopartículas de hematita. Os materiais foram caracterizados por difração de raios X, microscopia eletrônica de transmissão e determinação da área superficial específica e porosidade com base nas isotermas de adsorção/dessorção de N2. Foram realizados os ensaios de ecotoxicidade usando os protocolos padronizados para bioluminescência com Vibrio fischeri, letalidade da Artemia sp., germinação de sementes de Lactuca sativa L. (alface) e crescimento das raízes de Allium cepa L. (cebola). Os resultados de toxicidade indicaram estabilidade das nanopartículas, que não são alteradas significativamente pela ação do ozônio em meio aquoso. Para todas as amostras, os valores indicaram baixa ou nenhuma toxicidade nas condições dos experimentos, para os bioindicadores utilizados. Esses resultados fornecem indicação de que as nanopartículas de ferro recuperadas da indústria de resíduos podem ser usadas como catalisadores sem efeitos adversos ao meio ambiente.

ABSTRACT Iron oxides recovered from acid mine drainage represent a potential raw material for the low-cost production of nanogoethite or nanohematite, with a degree of purity suitable for its use as a catalyst in processes for treating liquid effluents with ozone. Thus, the toxicity of iron nanoparticles needs to be determined to predict their impact on the environment, before and after they have been used in these processes. In this context, the objective of this study was to evaluate the toxicity of nanogoethite and nanohematite produced from acid mine drainage as well as to compare the results with high-purity synthetic hematite. Nanogoethite was obtained from acid mine drainage and, after its heat treatment at 450°C, produced nanoparticles of hematite. The materials were characterized by X-ray diffraction, transmission electron microscopy, and determination of the specific surface area and porosity based on N2 adsorption/desorption isotherms. Ecotoxicity tests were carried out using standardized protocols for bioluminescence with Vibrio fischeri, lethality of Artemia sp, germination of Lactuca sativa L (lettuce) seeds, and growth of Allium cepa L (onion) roots. The toxicity results indicated stability of the nanoparticles, which are not significantly altered by the action of ozone in aqueous medium. For all samples, the values indicated low or no toxicity under the conditions of the experiments. These results provide an indication that the iron nanoparticles recovered from the waste industry can be used as catalysts without adverse effects on the environment.

Residue-based iron oxide catalyst for the degradation of simulated petrochemical wastewater via heterogeneous photo-Fenton process.

Iron oxide with a high degree of purity was recovered from waste and used as an environmentally friendly, low-cost catalyst in the application of the photo-Fenton process to simulated petrochemical wastewater (SPW). Iron oxide nanoparticles were characterized by X-ray powder diffraction, transmission electron microscopy, N2 adsorption/desorption isotherms, zeta potential, toxicity and atomic absorption spectrometry. The experiments were performed in a batch photochemical reactor, at 20 ± 2.0°C and pH 3.0. The SPW was efficiently mineralized and oxidized using a low catalyst dosage. The results showed that the organic compounds present in the wastewater were not adsorbed onto the solid surface. The solid was found to be stable with negligible leaching and low toxicity. The kTOC/kCOD ratios were calculated and varied according to the process: for a homogeneous reaction, the ratio obtained was 0.31 and for the heterogenous photo-Fenton process, it was closer to 1. The chemical oxygen demand and total organic carbon removal values were very close, indicating that the SPW is immediately mineralized, without producing partially oxidized compounds. The residue-based goethite studied represents a good alternative to commercially available catalysts in terms of sources and availability.