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Dye-laden sludge-derived biochar for wastewater remediation: A review on pyrolytic engineering, adsorptive interactions, and environmental prospects

Anshuman Gupta, Sandra Ramachandran, Neelaambhigai Mayilswamy, Amrita Nighojkar, Balasubramanian Kandasubramanian

2025Sustainable Chemistry for the Environment11 citationsDOIOpen Access PDF

Abstract

The persistent release of synthetic dyes from industrial effluents constitutes a substantial ecological and toxicological hazard owing to their persistent molecular structure and biological recalcitrance. This review presents a focused evaluation of biochar derived from dye-laden sewage sludge (DLSS-B), highlighting its potential as a low-cost, sustainable adsorbent for dye removal from wastewater. DLSS, a byproduct rich in organic matter, inorganic minerals, and residual dyes, is thermochemically converted into biochar through pyrolysis. A critical assessment is conducted on how variations in pyrolysis temperature, thermal ramping rate, and inert gas environment influence the resultant biochar’s specific surface area (reaching up to 405 m²/g), pore architecture, and surface functional chemistry. DLSS-B exhibits high adsorption capacities ranging from 200 to 405 mg/g for dyes such as malachite green and crystal violet, primarily through π–π stacking, electrostatic interactions, and hydrogen bonding. Chemical modifications, including acid/alkali activation and metal doping, further enhance its adsorptive performance. Regeneration studies show that DLSS-B can retain up to 92% efficiency over five cycles, indicating strong reusability. Beyond dye removal, secondary applications such as soil amendment (non-food use) and energy recovery (~20 MJ/kg) are discussed. This review emphasizes the integrated role of pyrolysis engineering, surface chemistry, and reuse strategies in developing DLSS-B as a viable material for industrial dye remediation.

Topics & Concepts

BiocharPyrolytic carbonEnvironmental remediationEnvironmental scienceWaste managementWastewaterSoil remediationEnvironmental chemistryPyrolysisPulp and paper industryEnvironmental engineeringChemistrySoil contaminationEngineeringContaminationSoil waterSoil scienceEcologyBiologyAdsorption and biosorption for pollutant removalEnvironmental remediation with nanomaterialsNanomaterials for catalytic reactions
Dye-laden sludge-derived biochar for wastewater remediation: A review on pyrolytic engineering, adsorptive interactions, and environmental prospects | Litcius