Sorption of brilliant green dye using soybean straw-derived biochar: characterization, kinetics, thermodynamics and toxicity studies

The present study was aimed to investigate brilliant green (BG) dye sorption onto soybean straw biochar (SSB) prepared at 800 °C and further understanding the sorption mechanism. Sorption kinetic models such as pseudo-first and pseudo-second order were executed for demonstrating sorption mechanism b...

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Bibliographic Details
Published in:Environmental geochemistry and health 2021-08, Vol.43 (8), p.2913-2926
Main Authors: Vyavahare, Govind, Gurav, Ranjit, Patil, Ravishankar, Sutar, Shubham, Jadhav, Pooja, Patil, Devashree, Yang, Yung-Hun, Tang, Jingchun, Chavan, Chetan, Kale, Sangeeta, Jadhav, Jyoti
Format: Article
Language:English
Subjects:
Adsorption
Analytical methods
Biomass
Charcoal
Chemisorption
Color removal
Correlation coefficient
Correlation coefficients
Dyes
Earth and Environmental Science
Electron microscopy
Environment
Environmental Chemistry
Environmental Health
Fourier transforms
Geochemistry
Glycine max
Gravimetric analysis
Hydrogen-Ion Concentration
Incubation period
Infrared analysis
Infrared spectroscopy
Kinetics
Multilayers
Original Paper
pH effects
Public Health
Quaternary Ammonium Compounds - chemistry
Scanning electron microscopy
Soil Science & Conservation
Sorbents
Sorption
Soybeans
Straw
Temperature
Terrestrial Pollution
Textile industry wastewaters
Thermodynamics
Toxicity
Wastewater
Wastewater pollution
Water Pollutants, Chemical
X-ray diffraction
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Summary:The present study was aimed to investigate brilliant green (BG) dye sorption onto soybean straw biochar (SSB) prepared at 800 °C and further understanding the sorption mechanism. Sorption kinetic models such as pseudo-first and pseudo-second order were executed for demonstrating sorption mechanism between the dye and biochar. Results of kinetics study were fitted well to pseudo-second-order kinetic model ( R 2 0.997) indicating that the reaction followed chemisorption mechanism. Furthermore, the effect of various parameters like sorbent dose, dye concentration, incubation time, pH and temperature on dye sorption was also studied. The maximum dye removal percentage and sorption capacity for SSB (800 °C) within 60 min were found to be 99.73% and 73.50 mg g − 1 , respectively, at pH 8 and 60 °C temperature, whereas adsorption isotherm studies showed a higher correlation coefficient values for Freundlich model ( R 2 0.990–0.996) followed by Langmuir model suggesting that sorption process was multilayer. The characterization of biomass and biochar was performed with the aid of analytical techniques like scanning electron microscopy (SEM), Fourier-transform infrared spectroscopy (FTIR), Brunauer–Emmett–Teller (BET) theory, X-ray diffraction (XRD) and thermo-gravimetric analysis (TGA). FTIR analysis showed active groups on biochar surface. BET study revealed higher surface area of biochar (194.7 m 2 /g) than the biomass (12.84 m 2 /g). Besides, phyto- and cytogenotoxic studies revealed significant decrease in the toxicity of dye containing water after treating with SSB. Therefore, this study has proved the sorption potential of soybean straw biochar for BG dye and could be further considered as sustainable cost-effective strategy for treating the textile dye-contaminated wastewater.
ISSN:0269-4042
1573-2983
DOI:10.1007/s10653-020-00804-y