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Macroalgae and coal-based biochar as a sustainable bioresource reuse for treatment of textile wastewater

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Abstract

Conventional wastewater treatment technologies are energy-intensive and environmentally un-friendly due to the use of synthetic and expensive chemicals. This study investigates the potential of macroalgae and coal-based biochar (control) to remove methylene blue from simulated wastewater as well as real textile wastewater. The macroalgae and coal-based biochars adsorb more than 90% of methylene blue from simulated wastewater in only 10 min on their active surface sites. The distinct feature of the current study is that macroalgae-based biochar shows high dye removal efficiency (75%) even in real textile wastewater. Macroalgae-based biochar also shows 67% dye removal efficiency for second regeneration cycle. Langmuir isotherm (> R2 = 0.954) and pseudo-second-order models (R2 = 0.999) are well fitted to describe the monolayer homogenous biosorption and process kinetics, respectively. Thermodynamic analysis indicates that methylene blue biosorption on macroalgae and coal-based biochars is a spontaneous and endothermic process following physiosorption. The maximum biosorption capacity with macroalgae-based biochar is 353.9 mg g−1 at 303 K, which is approximately 27% higher than any previous biochar study on the treatment of methylene blue. It demonstrates that macroalgae-based biochars can be used as a promising alternative adsorbent to activated carbon for textile wastewater treatment.

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Abbreviations

BC:

Biochar

SM:

Simple dry macroalgae

MBCs:

Macroalgae-based biochars

MBC450:

Macroalgae pyrolized at 450 °C

MBC550:

Macroalgae pyrolized at 550 °C

MBC650:

Macroalgae pyrolized at 650 °C

CBCs:

Coal-based biochars

CBC450:

Coal pyrolized at 450 °C

CBC550:

Coal pyrolized at 550 °C

CBC650:

Coal pyrolized at 650 °C

MB:

Methylene Blue

RTWW:

Real textile wastewater

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Acknowledgments

This work has been performed in CUI, Lahore Campus, Pakistan. MSU Rehman, F Rehman, and T Fazal acknowledge research grant under NRPU (2014) Project No. 4547 and F Javed and N Rashid acknowledge NRPU (2016) Project No. 3982 by Higher Education Commission (HEC), Pakistan.

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Fazal, T., Faisal, A., Mushtaq, A. et al. Macroalgae and coal-based biochar as a sustainable bioresource reuse for treatment of textile wastewater. Biomass Conv. Bioref. 11, 1491–1506 (2021). https://doi.org/10.1007/s13399-019-00555-6

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