Removal of Arsenic (III) from groundwater applying a reusable Mg-Fe-Cl layered double hydroxide

Removal of Arsenic (III) from groundwater applying a reusable Mg-Fe-Cl layered double hydroxide

BACKGROUND Layered double hydroxide compounds (LDHs) have been applied for the removal of oxyanions including arsenate (As(V)). However, the aim of this present research is to develop a LDH to treat arsenite (As(III)). Both batch and column sorption studies were conducted to assess the effect of LDH...

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Published in:Journal of chemical technology and biotechnology (1986) Vol. 90; no. 6; pp. 1160 - 1166
Main Authors: Jiang, Jia-Qian, Ashekuzzaman, S.M., Hargreaves, Justin S. J., McFarlane, Andrew R., Badruzzaman, A Borhan M, Tarek, Mehedi Hasan
Format: Journal Article
Language:English
Published: Chichester, UK John Wiley & Sons, Ltd 01-06-2015
Wiley Subscription Services, Inc
Subjects:
arsenic removal
Contact
desorption
drinking water treatment
Groundwater
Hydroxides
layered double hydroxide (LDH)
Magnesium
Sorbents
Sorption
sorption, desorption
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Abstract BACKGROUND Layered double hydroxide compounds (LDHs) have been applied for the removal of oxyanions including arsenate (As(V)). However, the aim of this present research is to develop a LDH to treat arsenite (As(III)). Both batch and column sorption studies were conducted to assess the effect of LDH dosage, contact time, solution pH and initial As(III) concentrations on the As(III) removal performance. The potential re‐use of this sorbent was also investigated. RESULTS For 2 g L−1 of Mg‐Fe‐Cl LDH, As(III) in test solution can be reduced from 400 µg L−1 to <10 µg L−1 after a contact time of 2 h. High As(III) concentration in Bangladesh groundwater can be reduced to meet the national drinking water standards (<50 µg L−1). The maximum adsorption capacity of As(III) by Mg‐Fe‐Cl LDH is 14.6 mg g−1‐LDH. Further, reusability of this sorbent was at least 20 cycles of regeneration with effective As(III) removal between 93.0 and 98.5%. Moreover, As(III) removal was unaffected by the solution pH but affected by the co‐existing competing anions and concentration of As(III). Finally, the main mechanism of As(III) removal by Mg‐Fe‐Cl LDH was suggested to be chemical sorption together with anion and ligand exchange with interlayer Cl− and OH− ions. CONCLUSION High efficiency of sorption of As(III) by the developed Mg‐Fe‐Cl LDH was demonstrated in this study which is generally not the case for most other sorbent materials. Pilot‐scale trials are needed to explore the suitability of full application of the developed Mg‐Fe‐Cl LDH for the removal of As(III). © 2014 Society of Chemical Industry
AbstractList BACKGROUND Layered double hydroxide compounds (LDHs) have been applied for the removal of oxyanions including arsenate (As(V)). However, the aim of this present research is to develop a LDH to treat arsenite (As(III)). Both batch and column sorption studies were conducted to assess the effect of LDH dosage, contact time, solution pH and initial As(III) concentrations on the As(III) removal performance. The potential re-use of this sorbent was also investigated. RESULTS For 2 g L super(-1) of Mg-Fe-Cl LDH, As(III) in test solution can be reduced from 400 mu g L super(-1) to <10 mu g L super(-1) after a contact time of 2 h. High As(III) concentration in Bangladesh groundwater can be reduced to meet the national drinking water standards (<50 mu g L super(-1)). The maximum adsorption capacity of As(III) by Mg-Fe-Cl LDH is 14.6 mg g super(-1)-LDH. Further, reusability of this sorbent was at least 20 cycles of regeneration with effective As(III) removal between 93.0 and 98.5%. Moreover, As(III) removal was unaffected by the solution pH but affected by the co-existing competing anions and concentration of As(III). Finally, the main mechanism of As(III) removal by Mg-Fe-Cl LDH was suggested to be chemical sorption together with anion and ligand exchange with interlayer Cl super(-) and OH super(-) ions. CONCLUSION High efficiency of sorption of As(III) by the developed Mg-Fe-Cl LDH was demonstrated in this study which is generally not the case for most other sorbent materials. Pilot-scale trials are needed to explore the suitability of full application of the developed Mg-Fe-Cl LDH for the removal of As(III). copyright 2014 Society of Chemical Industry
BACKGROUND Layered double hydroxide compounds (LDHs) have been applied for the removal of oxyanions including arsenate (As(V)). However, the aim of this present research is to develop a LDH to treat arsenite (As(III)). Both batch and column sorption studies were conducted to assess the effect of LDH dosage, contact time, solution pH and initial As(III) concentrations on the As(III) removal performance. The potential re-use of this sorbent was also investigated. RESULTS For 2 g L-1 of Mg-Fe-Cl LDH, As(III) in test solution can be reduced from 400 µg L-1 to <10 µg L-1 after a contact time of 2 h. High As(III) concentration in Bangladesh groundwater can be reduced to meet the national drinking water standards (<50 µg L-1). The maximum adsorption capacity of As(III) by Mg-Fe-Cl LDH is 14.6 mg g-1-LDH. Further, reusability of this sorbent was at least 20 cycles of regeneration with effective As(III) removal between 93.0 and 98.5%. Moreover, As(III) removal was unaffected by the solution pH but affected by the co-existing competing anions and concentration of As(III). Finally, the main mechanism of As(III) removal by Mg-Fe-Cl LDH was suggested to be chemical sorption together with anion and ligand exchange with interlayer Cl- and OH- ions. CONCLUSION High efficiency of sorption of As(III) by the developed Mg-Fe-Cl LDH was demonstrated in this study which is generally not the case for most other sorbent materials. Pilot-scale trials are needed to explore the suitability of full application of the developed Mg-Fe-Cl LDH for the removal of As(III). © 2014 Society of Chemical Industry
BACKGROUND Layered double hydroxide compounds (LDHs) have been applied for the removal of oxyanions including arsenate (As(V)). However, the aim of this present research is to develop a LDH to treat arsenite (As(III)). Both batch and column sorption studies were conducted to assess the effect of LDH dosage, contact time, solution pH and initial As(III) concentrations on the As(III) removal performance. The potential re‐use of this sorbent was also investigated. RESULTS For 2 g L−1 of Mg‐Fe‐Cl LDH, As(III) in test solution can be reduced from 400 µg L−1 to <10 µg L−1 after a contact time of 2 h. High As(III) concentration in Bangladesh groundwater can be reduced to meet the national drinking water standards (<50 µg L−1). The maximum adsorption capacity of As(III) by Mg‐Fe‐Cl LDH is 14.6 mg g−1‐LDH. Further, reusability of this sorbent was at least 20 cycles of regeneration with effective As(III) removal between 93.0 and 98.5%. Moreover, As(III) removal was unaffected by the solution pH but affected by the co‐existing competing anions and concentration of As(III). Finally, the main mechanism of As(III) removal by Mg‐Fe‐Cl LDH was suggested to be chemical sorption together with anion and ligand exchange with interlayer Cl− and OH− ions. CONCLUSION High efficiency of sorption of As(III) by the developed Mg‐Fe‐Cl LDH was demonstrated in this study which is generally not the case for most other sorbent materials. Pilot‐scale trials are needed to explore the suitability of full application of the developed Mg‐Fe‐Cl LDH for the removal of As(III). © 2014 Society of Chemical Industry
Author Badruzzaman, A Borhan M
Jiang, Jia-Qian
Hargreaves, Justin S. J.
Ashekuzzaman, S.M.
McFarlane, Andrew R.
Tarek, Mehedi Hasan
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  givenname: S.M.
  surname: Ashekuzzaman
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  organization: School of Engineering and Built Environment, Glasgow Caledonian University, Glasgow G4 0BA, Scotland, UK
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  givenname: Justin S. J.
  surname: Hargreaves
  fullname: Hargreaves, Justin S. J.
  organization: School of Chemistry, WestCHEM, Joseph Black Building, University of Glasgow, Glasgow G12 8QQScotland, UK
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  givenname: Andrew R.
  surname: McFarlane
  fullname: McFarlane, Andrew R.
  organization: School of Chemistry, WestCHEM, Joseph Black Building, University of Glasgow, Glasgow G12 8QQScotland, UK
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  givenname: A Borhan M
  surname: Badruzzaman
  fullname: Badruzzaman, A Borhan M
  organization: Department of Civil Engineering, Bangladesh University of Engineering and Technology, Dhaka-1000, Bangladesh
– sequence: 6
  givenname: Mehedi Hasan
  surname: Tarek
  fullname: Tarek, Mehedi Hasan
  organization: Department of Civil Engineering, Bangladesh University of Engineering and Technology, Dhaka-1000, Bangladesh
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Snippet BACKGROUND Layered double hydroxide compounds (LDHs) have been applied for the removal of oxyanions including arsenate (As(V)). However, the aim of this...
BACKGROUND Layered double hydroxide compounds (LDHs) have been applied for the removal of oxyanions including arsenate (As(V)). However, the aim of this...
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SubjectTerms arsenic removal
Contact
desorption
drinking water treatment
Groundwater
Hydroxides
layered double hydroxide (LDH)
Magnesium
Sorbents
Sorption
sorption, desorption
Title Removal of Arsenic (III) from groundwater applying a reusable Mg-Fe-Cl layered double hydroxide
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