Carvão ativado magnético para o tratamento de efluentes da indústria cafeeira
Resumen
As the planet’s largest natural resource, water plays a vital role in agriculture, industry,
and housing. Although more than 70% of the Earth’s surface is covered by water, only 3%
is freshwater. and less than 1% is suitable for drinking. In this context, the advancement
of new technologies for treating wastewater from various sectors of society, such as the
coffee agroindustry, is crucial for economic and environmental development. Coffee, being
the second most consumed beverage globally, generates a significant amount of wastewater
during its wet processing, resulting in the discharge of effluents containing high levels
of organic compounds, such as phenolic compounds, which, if improperly discarded, can
cause serious environmental damage. Among these compounds, chlorogenic acid stands
out. Thus, this project aims to develop activated carbon with iron nanoparticles from
sugarcane bagasse for the treatment of wastewater from the coffee agroindustry, as well as
to study its morphological and physicochemical properties. For the preparation of activated
carbon containing magnetic iron nanoparticles, sugarcane bagasse was used as the raw
material, which was mixed with a polymer produced by a modified Pechini method. After
mixing the sugarcane bagasse with the polymer, the material was subjected to physical
activation. Thus, the combination of the adsorptive properties of activated carbon with
the characteristics of the magnetic properties of the nanoparticles incorporated into the
material may significantly simplify the separation and reuse of the adsorbent from the
reaction environment. These operations are crucial since the economic viability of the
process is directly linked to its regeneration and reuse. The results indicate that the
material developed possesses an excellent adsorption capacity for the removal of phenol
and chlorogenic acid used as a model molecule. Furthermore, It was determined that
the method used to incorporate the iron nanoparticles, with magnetic properties, was
successful, as evidenced by X-ray diffraction (XRD) analysis, high-resolution transmission
electron microscopy (HR-TEM), and vibrating sample magnetometry (VSM).
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