Heavy metal pollution is a major problems in the environment. The impact of toxic metal ions can be minimized by different technologies, viz., chemical precipitation, membrane filtration, oxidation, reverse osmosis, flotation and adsorption. But among them, adsorption was found to be very efficient and common due to the low concentration of metal uptake and economically feasible properties. In this review paper, Fe–Mn binary oxide incorporated into diatomite (Fe/Mn-diatomite) was prepared by a simple coating method , and removal of Cu(II) from aqueous solutions. The effects of three independent variables including initial ion concentration, removal time, and adsorbent dosage were investigated on the maximum adsorption of Cu (II). The optimum conditions for the adsorption of Cu(II) was obtained: 75 ppm of initial ion concentration, 150 min of removal time and 1.5 g/l of adsorbent. The maximum removal efficiencies of Cu(II) was obtained 86.25%. The results showed that Fe/Mn-diatomite was apable of treating copper metal in wastewater.
Environmental issues such as the wastewater have influenced each aspect of our lives. For human and environmental health protection, it is necessary to remove excess zinc in industrial wastewaters before discharging them to environment. Modified diatomite displayed larger surface area and pore volumes in comparison with untreated natural diatomite, which favored heavy metals sorption behavior. In this study, the removal of Zn(II) ions from aqueous solution was studied using Fe/Mn modified diatomite sample at different adsorption parameters such as contact initial metal ions concentration, dosage of Fe/Mn-Diatomite and ionic strength Na2CO3 on ionic Zn2+ adsorption capacity of diatomite modified. The residual zinc concentration in the solution was determined using flame atomic absorption spectroscopy. The results showed that: the gravitational increase increases with increasing time and then becomes almost stable, with 120 minutes timeliness; absorption increases when Fe/Mn-Ditomite is increased, absorption reaches 89.48% at a dose of 1.5 g/l; additional different concentrations Na2CO3 ranged from 0 ppm to 80 ppm the results showed that performance treatment Zn2+ of correspond 94,85%.
This study could lay an essential foundation to develop modified diatomite for heavy metal removal from wastewater.
Publication Information
Publisher
Thu Dau Mot University, Viet Nam
Honorary Editor-in-Chief and Chairman of the Editorial Board
Assoc. Prof. Nguyen Van Hiep
Deputy Editor-in-Chief
PhD. Trần Hạnh Minh Phương Thu Dau Mot University
Editorial Board
Prof. Tran Van Doan Fujen University, Taiwan
Prof. Zafar Uddin Ahmed Vietnam National University Ho Chi Minh City
Prof.Dr. Phillip G.Cerny The University of Manchester, United Kingdom
Prof. Ngo Van Le University of Social Sciences and Humanities (VNU-HCM)
Prof. Bui The Cuong Southern Institute of Social Sciences
Prof. Le Quang Tri Can Tho University
Assoc. Prof. Nguyen Van Duc Animal Husbandry Association of Vietnam
Assoc. Prof. Ted Yuchung Liu National Pingtung University, Taiwan
PhD. Anita Doraisami Economics Monash University, Australia
Prof. Dr. Andrew Seddon Asia Pacific University of Technology & innovation (APU)
Assoc. Prof. Le Tuan Anh Thu Dau Mot University
Prof. Abtar Darshan Singh Asia Pacific University, Malaysia
Prof.Dr. Ron W.Edwards The University of Melbourne, Australia
Assoc. Prof. Hoang Xuan Nien Thu Dau Mot University
PhD. Nguyen Duc Nghia Vietnam National University Ho Chi Minh City
PhD. Bao Dat Monash University (Australia)
PhD. Raqib Chowdhury Monash University (Australia)
PhD. Nguyen Hoang Tuan Thu Dau Mot University
PhD. Nguyen Thi Lien Thuong Thu Dau Mot University