AI Article Synopsis

  • Methylene blue (MB), a carcinogenic dye prevalent in printing and textile industries, poses environmental challenges due to its high concentration in industrial discharge, necessitating effective removal methods.
  • This research introduces a novel magnetized biochar (γ-FeO-LSB) synthesized from Lagenaria siceraria peels, demonstrating superior magnetic properties and greater surface area compared to conventional biochar, making it potentially more effective in dye removal.
  • The adsorption studies indicate that γ-FeO-LSB can efficiently remove MB dye under varying conditions, showing a maximum adsorption capacity of 54.55 mg/g, and it remains effective for up to four cycles, all while being cost-effective to produce.

Article Abstract

In the printing and textile industries, methylene blue (a cationic azo dye) is commonly used. MB is a well-known carcinogen, and another major issue is its high content in industrial discharge. There are numerous removal methodologies that have been employed to remove it from industrial discharge; however, these current modalities have one or more limitations. In this research, a novel magnetized biochar (γ-FeO-LSB) was synthesized using Lagenaria siceraria peels which were further magnetized via the co-precipitation method. The synthesized γ-FeO-LSB was characterized using FTIR, X-ray diffraction, Raman, SEM-EDX, BET, and vibrating sample magnetometry (VSM) for the analysis of magnetic properties. γ-FeO-LSB showed a reversible type IV isotherm, which is a primary characteristic of mesoporous materials. γ-FeO-LSB had a specific surface area (S = 135.30 m/g) which is greater than that of LSB (S = 11.54 m/g). γ-FeO-LSB exhibits a saturation magnetization value (Ms) of 3.72 emu/g which shows its superparamagnetic nature. The batch adsorption process was performed to analyze the adsorptive removal of MB dye using γ-FeO-LSB. The adsorption efficiency of γ-FeO-LSB for MB was analyzed by varying parameters like the initial concentration of adsorbate (MB), γ-FeO-LSB dose, pH effect, contact time, and temperature. Adsorption isotherm, kinetic, and thermodynamics were also studied after optimizing the protocol. The non-linear Langmuir model fitted the best to explain the adsorption isotherm mechanism and resulting adsorption capacity ( =54.55 mg/g). The thermodynamics study showed the spontaneous and endothermic nature, and pseudo-second-order rate kinetics was followed during the adsorption process. Regeneration study showed that γ-FeO-LSB can be used up to four cycles. In laboratory setup, the cost of γ-FeO-LSB synthesis comes out to be 162.75 INR/kg which is low as compared to commercially available adsorbents. The results obtained suggest that magnetic Lagenaria siceraria biochar, which is economical and efficient, can be used as a potential biochar material for industrial applications in the treatment of wastewater.

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Source
http://dx.doi.org/10.1007/s11356-024-33477-6DOI Listing

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