Add to ORKGHighly toxic nickel is released into the environment from a number of industrial processes, but current techniques for its removal are expensive and may cause secondary pollution. We developed a biosorbent of chitosan-immobilized brown algae (Laminaria japonica). The effects of different parameters on the adsorption capacity and biosorption-desorption of Ni2+ from aqueous solution were evaluated. Kinetic studies showed that the adsorption of Ni2+ by the immobilized algal beads followed second-order kinetics. When the adsorbent dose was increased, the biosorption capacity decreased and the removal efficiency increased. Ni2+ biosorption by the immobilized algae cell beads was a good fit for the Langmuir and Freundlich isotherm models. In addi...
Methods of physical and chemical adsorption of heavy metals have disadvantages in some ways- such as...
Two living Chlorella species were used to remove nickel from solution containing 30 mug Ni ml(-1) in...
In this paper, marine brown algae Laminaria japonica was chemically modified by crosslinking with ep...
Highly toxic nickel is released into the environment from a number of industrial processes, but curr...
Discharging of electroplating effluent containing nickel (II) ion would imposed severe impacts on th...
Background: The kinds of pollutants such as heavy metals, especially, can be removed from water and ...
Abstract: Removal of Ni(II) from aqueous solutions by biosorption on dried green algae Oscillatoria ...
The present study compared the efficiency of two unicellular green algae, Chlorella vulgaris (a comm...
In the present work, various forms of algae Pelvetia canaliculata were prepared by different chemica...
One of the effective methods for the separation and recovery of heavy metals from aqueous solutions ...
The batch removal of Ni2+ from aqueous solution and wastewater using marine dried (MD) red algae Gra...
The use of biosorbent for heavy metal removal has revealed enormous potential of algae for biosorpti...
This study focused on the batch removal of Cu2+ and Ni2+ ions from an aqueous solution and wastewate...
The adsorption of Ni(II) onto blue green marine algae (BGMA) in batch conditions is being investigat...
Abstract Biosorption studies in batch mode were carried out to investigate the adsorption of Ni(II) ...
Methods of physical and chemical adsorption of heavy metals have disadvantages in some ways- such as...
Two living Chlorella species were used to remove nickel from solution containing 30 mug Ni ml(-1) in...
In this paper, marine brown algae Laminaria japonica was chemically modified by crosslinking with ep...
Highly toxic nickel is released into the environment from a number of industrial processes, but curr...
Discharging of electroplating effluent containing nickel (II) ion would imposed severe impacts on th...
Background: The kinds of pollutants such as heavy metals, especially, can be removed from water and ...
Abstract: Removal of Ni(II) from aqueous solutions by biosorption on dried green algae Oscillatoria ...
The present study compared the efficiency of two unicellular green algae, Chlorella vulgaris (a comm...
In the present work, various forms of algae Pelvetia canaliculata were prepared by different chemica...
One of the effective methods for the separation and recovery of heavy metals from aqueous solutions ...
The batch removal of Ni2+ from aqueous solution and wastewater using marine dried (MD) red algae Gra...
The use of biosorbent for heavy metal removal has revealed enormous potential of algae for biosorpti...
This study focused on the batch removal of Cu2+ and Ni2+ ions from an aqueous solution and wastewate...
The adsorption of Ni(II) onto blue green marine algae (BGMA) in batch conditions is being investigat...
Abstract Biosorption studies in batch mode were carried out to investigate the adsorption of Ni(II) ...
Methods of physical and chemical adsorption of heavy metals have disadvantages in some ways- such as...
Two living Chlorella species were used to remove nickel from solution containing 30 mug Ni ml(-1) in...
In this paper, marine brown algae Laminaria japonica was chemically modified by crosslinking with ep...