Current perspectives, recent advancements, and efficiencies of various dye-containing wastewater treatment technologies
Current perspectives, recent advancements, and efficiencies of various dye-containing wastewater treatment technologies
The usage of dyes is increasing due to their high demand in expanding industrial sector. As a result, large volumes of dye wastewater are being generated, particularly in the textile industry. Colored effluent discharged by industrial processes into surface water bodies negatively affects aquatic, human, and animal life, which is a major global concern. To reduce the detrimental effects of dye wastewater on the environment, it should be treated before its disposal. This article extensively reviews the existing and advancements in physical, physicochemical, chemical, and biological treatment technologies and their efficacies in dye removal (%). Also, the article summarized the benefits and challenges associated with the existing methods to use them at an industrial scale. The physical, physicochemical, and chemical methods have less hydraulic retention time (HRT), from minutes to a few hours, and higher removal efficiencies (85–100 %). However, certain drawbacks hinder their widespread use, such as limited regenerative capacities of adsorbents, filtration associated with high fouling rates of the membrane, higher costs of ion exchange, sludge production in coagulation-flocculation, high treatment cost and high dissolved oxygen requirement in sonocatalysis and in chemical technologies: secondary pollutants production, sludge production, high cost, and ecological inefficiency. Biological-based treatment with bacteria, fungus, yeast, and algae has a bit higher HRT (a few hours to days) with removal efficiencies ranging between 85 and 100 % with the advantage of low cost, low energy requirement, less sludge, and being environmentally friendly. Developing an environmentally friendly and low-cost method is currently the need of the hour. Researchers have increasingly focused on bioremediation as an essential method for removing dangerous dye contaminants from natural water bodies. State of the art of bioremediation techniques has also been discussed from an economic and technological standpoint.
Khan, Mohammad Danish
94549b26-7db9-4ad9-a146-645a4192e1ab
Singh, Ankit
45302a33-7b87-4d4f-a319-56d4cc7528d8
Khan, Mohammad Zain
4e15243a-b96e-47fc-a969-32ccb1c2cce2
Tabraiz, Shamas
1aadf9c7-38fb-4112-ae42-d568853cee68
Sheikh, Javed
941aba1a-9fa2-4648-ad8f-220d48a2e39b
15 March 2023
Khan, Mohammad Danish
94549b26-7db9-4ad9-a146-645a4192e1ab
Singh, Ankit
45302a33-7b87-4d4f-a319-56d4cc7528d8
Khan, Mohammad Zain
4e15243a-b96e-47fc-a969-32ccb1c2cce2
Tabraiz, Shamas
1aadf9c7-38fb-4112-ae42-d568853cee68
Sheikh, Javed
941aba1a-9fa2-4648-ad8f-220d48a2e39b
Khan, Mohammad Danish, Singh, Ankit, Khan, Mohammad Zain, Tabraiz, Shamas and Sheikh, Javed
(2023)
Current perspectives, recent advancements, and efficiencies of various dye-containing wastewater treatment technologies.
Journal of Water Process Engineering, 53, [103579].
(doi:10.1016/j.jwpe.2023.103579).
Abstract
The usage of dyes is increasing due to their high demand in expanding industrial sector. As a result, large volumes of dye wastewater are being generated, particularly in the textile industry. Colored effluent discharged by industrial processes into surface water bodies negatively affects aquatic, human, and animal life, which is a major global concern. To reduce the detrimental effects of dye wastewater on the environment, it should be treated before its disposal. This article extensively reviews the existing and advancements in physical, physicochemical, chemical, and biological treatment technologies and their efficacies in dye removal (%). Also, the article summarized the benefits and challenges associated with the existing methods to use them at an industrial scale. The physical, physicochemical, and chemical methods have less hydraulic retention time (HRT), from minutes to a few hours, and higher removal efficiencies (85–100 %). However, certain drawbacks hinder their widespread use, such as limited regenerative capacities of adsorbents, filtration associated with high fouling rates of the membrane, higher costs of ion exchange, sludge production in coagulation-flocculation, high treatment cost and high dissolved oxygen requirement in sonocatalysis and in chemical technologies: secondary pollutants production, sludge production, high cost, and ecological inefficiency. Biological-based treatment with bacteria, fungus, yeast, and algae has a bit higher HRT (a few hours to days) with removal efficiencies ranging between 85 and 100 % with the advantage of low cost, low energy requirement, less sludge, and being environmentally friendly. Developing an environmentally friendly and low-cost method is currently the need of the hour. Researchers have increasingly focused on bioremediation as an essential method for removing dangerous dye contaminants from natural water bodies. State of the art of bioremediation techniques has also been discussed from an economic and technological standpoint.
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Accepted/In Press date: 10 February 2023
e-pub ahead of print date: 15 February 2023
Published date: 15 March 2023
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Local EPrints ID: 500178
URI: http://eprints.soton.ac.uk/id/eprint/500178
ISSN: 2214-7144
PURE UUID: 120c6979-4282-47d9-a965-4193a61e33c1
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Date deposited: 22 Apr 2025 17:00
Last modified: 23 Apr 2025 02:14
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Author:
Mohammad Danish Khan
Author:
Ankit Singh
Author:
Mohammad Zain Khan
Author:
Shamas Tabraiz
Author:
Javed Sheikh
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