y-Al2O3-based nanocomposite adsorbents for arsenic(V) removal: Assessing performance, toxicity and particle leakage
y-Al2O3-based nanocomposite adsorbents for arsenic(V) removal: Assessing performance, toxicity and particle leakage
The generation and development of effective adsorption materials for arsenic removal are urgently needed due to acute arsenic contamination of water sources in many regions around the world. In the search for these new adsorbents, the application of nanomaterials or nanocomposites, and especially the use of nanoparticles (NPs), has proven increasingly attractive. While the adsorptive performance of a range of nanocomposite and nanomaterial-based systems has been extensively reviewed in previously-published literature, the stability of these systems in terms of NP release, i.e. the ability of the nanomaterial or nanocomposite to retain incorporated NPs, is less well understood. Here we examine the performance of nanocomposites comprised of aluminium oxide nanoparticles (AluNPs) incorporated in macroporous polyacrylamide-based cryogels (n-Alu-cryo, where n indicates the percentage of AluNPs in the polymer material (n = 0–6%, w/v)) for As(V) adsorption, and evaluate AluNP leakage before and after the use of these materials. A range of techniques is utilised and assessed (SEM, TEM, mass weight change, PIXE and in vitro toxicity studies). The 4-Alu-cryo nanocomposite was shown to be optimal for minimising AluNP losses while maximising As(V) removal. From the same nanocomposite we were further able to show that NP losses were not detectable at the AluNP concentrations used in the study. Toxicity tests revealed that no cytotoxic effects could be observed. The cryogel-AluNPs composites were not only effective in As(V) removal but also in immobilising the AluNPs. More challenging flow-through conditions for the evaluation of NP leakage could be included as a next step in a continued study assessing particle loss and subsequent toxicity.
Composites, Adsorbents, Macroporous polymers, Nanoparticles, Aluminium oxide, Risk assessment
207-214
Önnby, Linda
88c8928e-b7ea-4e2b-9783-01659d681188
Svensson, Christian
bfe9b33e-c0fb-485b-82b8-cd31f9c700d3
Mbundi, Lubinda
282f5442-1a86-4728-8d31-f3c88669e982
Busquets, Rosa
d3f8511d-c34e-4bf7-956c-19e4c1c5949f
Cundy, Andrew
994fdc96-2dce-40f4-b74b-dc638286eb08
Kirsebom, Harald
75b60204-2231-4d74-ac08-b8df197f7dd5
1 March 2014
Önnby, Linda
88c8928e-b7ea-4e2b-9783-01659d681188
Svensson, Christian
bfe9b33e-c0fb-485b-82b8-cd31f9c700d3
Mbundi, Lubinda
282f5442-1a86-4728-8d31-f3c88669e982
Busquets, Rosa
d3f8511d-c34e-4bf7-956c-19e4c1c5949f
Cundy, Andrew
994fdc96-2dce-40f4-b74b-dc638286eb08
Kirsebom, Harald
75b60204-2231-4d74-ac08-b8df197f7dd5
Önnby, Linda, Svensson, Christian, Mbundi, Lubinda, Busquets, Rosa, Cundy, Andrew and Kirsebom, Harald
(2014)
y-Al2O3-based nanocomposite adsorbents for arsenic(V) removal: Assessing performance, toxicity and particle leakage.
Science of the Total Environment, 473-474, .
(doi:10.1016/j.scitotenv.2013.12.020).
Abstract
The generation and development of effective adsorption materials for arsenic removal are urgently needed due to acute arsenic contamination of water sources in many regions around the world. In the search for these new adsorbents, the application of nanomaterials or nanocomposites, and especially the use of nanoparticles (NPs), has proven increasingly attractive. While the adsorptive performance of a range of nanocomposite and nanomaterial-based systems has been extensively reviewed in previously-published literature, the stability of these systems in terms of NP release, i.e. the ability of the nanomaterial or nanocomposite to retain incorporated NPs, is less well understood. Here we examine the performance of nanocomposites comprised of aluminium oxide nanoparticles (AluNPs) incorporated in macroporous polyacrylamide-based cryogels (n-Alu-cryo, where n indicates the percentage of AluNPs in the polymer material (n = 0–6%, w/v)) for As(V) adsorption, and evaluate AluNP leakage before and after the use of these materials. A range of techniques is utilised and assessed (SEM, TEM, mass weight change, PIXE and in vitro toxicity studies). The 4-Alu-cryo nanocomposite was shown to be optimal for minimising AluNP losses while maximising As(V) removal. From the same nanocomposite we were further able to show that NP losses were not detectable at the AluNP concentrations used in the study. Toxicity tests revealed that no cytotoxic effects could be observed. The cryogel-AluNPs composites were not only effective in As(V) removal but also in immobilising the AluNPs. More challenging flow-through conditions for the evaluation of NP leakage could be included as a next step in a continued study assessing particle loss and subsequent toxicity.
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Published date: 1 March 2014
Keywords:
Composites, Adsorbents, Macroporous polymers, Nanoparticles, Aluminium oxide, Risk assessment
Organisations:
Geochemistry
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Local EPrints ID: 399274
URI: http://eprints.soton.ac.uk/id/eprint/399274
ISSN: 0048-9697
PURE UUID: b204b037-703d-4229-bdeb-aee5b734ca02
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Date deposited: 10 Aug 2016 10:50
Last modified: 15 Mar 2024 03:52
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Author:
Linda Önnby
Author:
Christian Svensson
Author:
Lubinda Mbundi
Author:
Rosa Busquets
Author:
Harald Kirsebom
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