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Removal of Heavy Metals from Industrial Wastewater Through Minerals
Abstract Heavy metals are toxic to the health and environment and causes harmful consequences to human beings. It is essential to take effective measures to remove metals from contaminated water. In this research, naturally available brick materials with different compositions collected from Kandy (type A), Gampaha (type B), and Embilipitiya (type C) areas were used to remove Cu, Cr and Pb ions. These brick materials are cost effective and are a readily available alternative to conventional heavy metal removal. The characterization of brick material is performed using X-Ray Fluorescence (XRF) and Nitrogen Adsorption – Desorption analyser. Calculated surface area and total pore volume and pore width of type A, B, and C are lie respectively, in the range of 128–154 m2/g, 0.24–0.45 cm3/g, and 5.6–16.7 nm. The main objective of this research is to investigate how the characteristics of adsorbents influences the adsorption process and to identify the best model to describe the kinetic and equilibrium adsorption to purify metal contaminated water. Results indicate that Pseudo – first – order kinetics model properly described the adsorption of Cu2+ to the brick type C, which has maximum adsorption capacity of 497 mg g−1. The adsorption process of Pb2+ to the brick type A and Cu2+ and Pb2+ to brick type B and C were well-fitted with Pseudo – second – order kinetics model. In equilibrium studies, the Langmuir isotherm showed a better fitness in adsorption of Cu2+ into brick type A and C, Pb2+ into brick type B, whereas the Freundlich isotherm well represented the adsorption characteristics of Cu2+ into brick type A, Pb2+ into brick type B and Cr6+ into all brick types. The comparison of results indicated that the use of brick types A, B, C can be used as a potential nan sorbent to remove heavy metals from industrial waste water.
Removal of Heavy Metals from Industrial Wastewater Through Minerals
Abstract Heavy metals are toxic to the health and environment and causes harmful consequences to human beings. It is essential to take effective measures to remove metals from contaminated water. In this research, naturally available brick materials with different compositions collected from Kandy (type A), Gampaha (type B), and Embilipitiya (type C) areas were used to remove Cu, Cr and Pb ions. These brick materials are cost effective and are a readily available alternative to conventional heavy metal removal. The characterization of brick material is performed using X-Ray Fluorescence (XRF) and Nitrogen Adsorption – Desorption analyser. Calculated surface area and total pore volume and pore width of type A, B, and C are lie respectively, in the range of 128–154 m2/g, 0.24–0.45 cm3/g, and 5.6–16.7 nm. The main objective of this research is to investigate how the characteristics of adsorbents influences the adsorption process and to identify the best model to describe the kinetic and equilibrium adsorption to purify metal contaminated water. Results indicate that Pseudo – first – order kinetics model properly described the adsorption of Cu2+ to the brick type C, which has maximum adsorption capacity of 497 mg g−1. The adsorption process of Pb2+ to the brick type A and Cu2+ and Pb2+ to brick type B and C were well-fitted with Pseudo – second – order kinetics model. In equilibrium studies, the Langmuir isotherm showed a better fitness in adsorption of Cu2+ into brick type A and C, Pb2+ into brick type B, whereas the Freundlich isotherm well represented the adsorption characteristics of Cu2+ into brick type A, Pb2+ into brick type B and Cr6+ into all brick types. The comparison of results indicated that the use of brick types A, B, C can be used as a potential nan sorbent to remove heavy metals from industrial waste water.
Removal of Heavy Metals from Industrial Wastewater Through Minerals
Muthukalum, U. A. S. L. (author) / Gunathilake, C. A. (author) / Kalpage, C. S. (author)
2019-08-07
18 pages
Article/Chapter (Book)
Electronic Resource
English
Heavy metals , Minerals , Adsorption , Specific surface area , Ion concentration Energy , Sustainable Architecture/Green Buildings , Civil Engineering , Sustainable Development , Climate Change/Climate Change Impacts , Water Policy/Water Governance/Water Management , Information Systems Applications (incl. Internet)
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