Adsorptive purification of heavy metal contaminated wastewater with sewage sludge derived carbon-supported Mg(II) composite

• Published in: The Science of the total environment Vol. 691; pp. 306 - 321
• Main Authors: Ngambia, Audrey, Ifthikar, Jerosha, Shahib, Irshad Ibran, Jawad, Ali, Shahzad, Ajmal, Zhao, Mengmeng, Wang, Jia, Chen, Zhulei, Chen, Zhuqi
• Format: Journal Article
• Language: English
• Published: Netherlands Elsevier B.V 15.11.2019
• Subjects: adsorbents; Adsorption; Biochar; Cadmium; carbonization; copper; coprecipitation; ecology; environmental factors; heavy metals; industry; ion exchange; lakes; Lead; magnesium; metal ions; MgO; moieties; pollutants; Sewage sludge; sewage treatment; silicates; silver; solid wastes; sorption isotherms; surface area; tap water; temperature; wastewater; water pollution; Lead; Cadmium; Adsorption; MgO; Biochar; Sewage sludge
• ISSN: 0048-9697; 1879-1026; 1879-1026
• DOI: 10.1016/j.scitotenv.2019.07.003

A rod-like SDBC-Mg(II) composite was synthesized and optimized in the conditions of 25% Mg(II) loading and 500 °C calcination temperature. As-prepared SDBC-25%Mg(II)-500 adsorbent attained equilibrium in 30 min, with an extraordinary capacity of 2931.76 mg g−1 (Pb(II)) and 861.11 mg g−1 (Cd(II)), revealing a promising adsorbent for the removal of such metals so far. The adsorption kinetics was well described by the pseudo-second-order model while the adsorption isotherm could be fitted by Redlich-Peterson model. Furthermore, SDBC-25%Mg(II)-500 has a high anti-interference and selectivity in the presence of competing ions/other environmental factors and, also effectively eliminates >99% of Pb2+, Cd2+, Ag+ and Cu2+ ions from pond water, lake water and tap water. The adsorption process demonstrated a synergetic adsorption mechanism comprised of ion exchange with Mg(II), coordination with surface and inner carboxylic or carbonyl functional groups and co-precipitations as metal silicates, which is responsible for its superb adsorption performance. Besides, surface carvings of Mg(II) and tunnels on the rods resulting from the sludge carbonization provided a high surface area (91.57 m2 g−1), extra sorption sites and room for easy pollutant diffusion which contributed to surface physical adsorption. Furthermore, this technique demonstrate an alternative pathway that will relieve the burdens of sewage sludge treatment process and turn this solid waste into highly efficient adsorbent for eliminating heavy metal ions from wastewater. This can be considered as a feasible waste resource utilization to meet with the requirement from both ecology and economy for auspicious applications in industries. [Display omitted] •A surface carved and nanorod-like SDBC-Mg(II) was synthesized through a facile precipitation-calcination route•Sewage sludge used as carbon source which aided to create porous structures, carved Mg(II) and tunnel paths•The approach of resource recovery from waste sewage sludge itself is indicative to the sludge free wastewater treatment