Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes
Producing nanomaterials from hazardous wastes for water and soil treatment is of great concern. Here, we produced and fully characterized two novel nanomaterials from sugar beet processing (SBR)- and brick factory-residuals (BFR) and assed their ability for Cd and Cu sorption in water and reducing m...
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ftunivthessaly:oai:ir.lib.uth.gr:11615/75694 2023-05-15T15:52:54+02:00 Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes Lashen Z.M., Shams M.S., El-Sheshtawy H.S., Slaný M., Antoniadis V., Yang X., Sharma G., Rinklebe J., Shaheen S.M., Elmahdy S.M. 2022 http://hdl.handle.net/11615/75694 https://doi.org/10.1016/j.jhazmat.2021.128205 en eng doi:10.1016/j.jhazmat.2021.128205 03043894 http://hdl.handle.net/11615/75694 Journal of Hazardous Materials https://www.scopus.com/inward/record.uri?eid=2-s2.0-85122328815&doi=10.1016%2fj.jhazmat.2021.128205&partnerID=40&md5=1509e9a399b4803e86931e064ff23eb1 Alkalinity Costs Hazardous materials Hazards Remediation Soil pollution Soils Solid wastes Sugar beets Water pollution Water treatment Clay bricks Contaminated soils Contaminated water Hazardous solid waste Hazardous wastes Low cost nanomaterial Low-costs Soils remediation Toxic metals Wastewater remediation Nanostructured materials cadmium calcium hydroxide carbonic acid copper phosphorus pentoxide carbohydrate heavy metal nanomaterial water carbonate industrial waste sorption sugar beet aqueous solution Article controlled study electric conductivity hazardous waste nanotechnology scanning electron microscopy journalArticle 2022 ftunivthessaly https://doi.org/10.1016/j.jhazmat.2021.128205 2023-02-02T17:36:15Z Producing nanomaterials from hazardous wastes for water and soil treatment is of great concern. Here, we produced and fully characterized two novel nanomaterials from sugar beet processing (SBR)- and brick factory-residuals (BFR) and assed their ability for Cd and Cu sorption in water and reducing metal availability in a contaminated soil. The SBR removed up to 99% of Cu and 91% of Cd in water, and exhibited a significantly faster and higher sorption capacity (qmax (g kg−1) = 1111.1 for Cu and 33.3 for Cd) than BFR (qmax (g kg−1) = 33.3 for Cu and 10.0 for Cd), even at acidic pH. Soil metal availability was significantly reduced by SBR (up to 57% for Cu and 86% for Cd) and BFR (up to 36% for Cu and 68% for Cd) compared to the unamended soil. The higher removal efficacy of SBR over BFR could be attributed to its higher alkalinity (pH = 12.5), carbonate content (82%), and specific surface area, as well as the activity of hydroxyl –OH and Si-O groups. The nano-scale SBR and BFR, the former particularly, are novel, of low cost, and environmental friendly amendments that can be used for the remediation of metal-contaminated water and soil. © 2022 Elsevier B.V. Article in Journal/Newspaper Carbonic acid University of Thessaly Institutional Repository Journal of Hazardous Materials 428 128205 |
institution |
Open Polar |
collection |
University of Thessaly Institutional Repository |
op_collection_id |
ftunivthessaly |
language |
English |
topic |
Alkalinity Costs Hazardous materials Hazards Remediation Soil pollution Soils Solid wastes Sugar beets Water pollution Water treatment Clay bricks Contaminated soils Contaminated water Hazardous solid waste Hazardous wastes Low cost nanomaterial Low-costs Soils remediation Toxic metals Wastewater remediation Nanostructured materials cadmium calcium hydroxide carbonic acid copper phosphorus pentoxide carbohydrate heavy metal nanomaterial water carbonate industrial waste sorption sugar beet aqueous solution Article controlled study electric conductivity hazardous waste nanotechnology scanning electron microscopy |
spellingShingle |
Alkalinity Costs Hazardous materials Hazards Remediation Soil pollution Soils Solid wastes Sugar beets Water pollution Water treatment Clay bricks Contaminated soils Contaminated water Hazardous solid waste Hazardous wastes Low cost nanomaterial Low-costs Soils remediation Toxic metals Wastewater remediation Nanostructured materials cadmium calcium hydroxide carbonic acid copper phosphorus pentoxide carbohydrate heavy metal nanomaterial water carbonate industrial waste sorption sugar beet aqueous solution Article controlled study electric conductivity hazardous waste nanotechnology scanning electron microscopy Lashen Z.M., Shams M.S., El-Sheshtawy H.S., Slaný M., Antoniadis V., Yang X., Sharma G., Rinklebe J., Shaheen S.M., Elmahdy S.M. Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes |
topic_facet |
Alkalinity Costs Hazardous materials Hazards Remediation Soil pollution Soils Solid wastes Sugar beets Water pollution Water treatment Clay bricks Contaminated soils Contaminated water Hazardous solid waste Hazardous wastes Low cost nanomaterial Low-costs Soils remediation Toxic metals Wastewater remediation Nanostructured materials cadmium calcium hydroxide carbonic acid copper phosphorus pentoxide carbohydrate heavy metal nanomaterial water carbonate industrial waste sorption sugar beet aqueous solution Article controlled study electric conductivity hazardous waste nanotechnology scanning electron microscopy |
description |
Producing nanomaterials from hazardous wastes for water and soil treatment is of great concern. Here, we produced and fully characterized two novel nanomaterials from sugar beet processing (SBR)- and brick factory-residuals (BFR) and assed their ability for Cd and Cu sorption in water and reducing metal availability in a contaminated soil. The SBR removed up to 99% of Cu and 91% of Cd in water, and exhibited a significantly faster and higher sorption capacity (qmax (g kg−1) = 1111.1 for Cu and 33.3 for Cd) than BFR (qmax (g kg−1) = 33.3 for Cu and 10.0 for Cd), even at acidic pH. Soil metal availability was significantly reduced by SBR (up to 57% for Cu and 86% for Cd) and BFR (up to 36% for Cu and 68% for Cd) compared to the unamended soil. The higher removal efficacy of SBR over BFR could be attributed to its higher alkalinity (pH = 12.5), carbonate content (82%), and specific surface area, as well as the activity of hydroxyl –OH and Si-O groups. The nano-scale SBR and BFR, the former particularly, are novel, of low cost, and environmental friendly amendments that can be used for the remediation of metal-contaminated water and soil. © 2022 Elsevier B.V. |
format |
Article in Journal/Newspaper |
author |
Lashen Z.M., Shams M.S., El-Sheshtawy H.S., Slaný M., Antoniadis V., Yang X., Sharma G., Rinklebe J., Shaheen S.M., Elmahdy S.M. |
author_facet |
Lashen Z.M., Shams M.S., El-Sheshtawy H.S., Slaný M., Antoniadis V., Yang X., Sharma G., Rinklebe J., Shaheen S.M., Elmahdy S.M. |
author_sort |
Lashen Z.M., Shams M.S., El-Sheshtawy H.S., Slaný M., Antoniadis V., Yang X., Sharma G., Rinklebe J., Shaheen S.M., Elmahdy S.M. |
title |
Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes |
title_short |
Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes |
title_full |
Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes |
title_fullStr |
Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes |
title_full_unstemmed |
Remediation of Cd and Cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes |
title_sort |
remediation of cd and cu contaminated water and soil using novel nanomaterials derived from sugar beet processing- and clay brick factory-solid wastes |
publishDate |
2022 |
url |
http://hdl.handle.net/11615/75694 https://doi.org/10.1016/j.jhazmat.2021.128205 |
genre |
Carbonic acid |
genre_facet |
Carbonic acid |
op_source |
Journal of Hazardous Materials https://www.scopus.com/inward/record.uri?eid=2-s2.0-85122328815&doi=10.1016%2fj.jhazmat.2021.128205&partnerID=40&md5=1509e9a399b4803e86931e064ff23eb1 |
op_relation |
doi:10.1016/j.jhazmat.2021.128205 03043894 http://hdl.handle.net/11615/75694 |
op_doi |
https://doi.org/10.1016/j.jhazmat.2021.128205 |
container_title |
Journal of Hazardous Materials |
container_volume |
428 |
container_start_page |
128205 |
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1766388003417096192 |