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Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review

Year 2018, Volume: 1 Issue: 3, 71 - 76, 02.07.2018

Abstract



Nanotechnology is considered
the future of the world in most physics and chemical solutions that cannot be
applied in many scale level. This review aimed to highlight the different uses
of nanotechnology in industrial waste water treatment system because it is very
important issue to protect the environment from the different liquid industrial
pollutants. Nanoparticles is defined by some as nanomaterials, and these
materials has unusual properties not present in ordinary materials. Nano,
typically employed as a prefix, is defined as one billionth of a quantity or term
that is represented mathematically 10 9-. Generally, refers to the
processes that produces and use matter at the nanometre level. From the review
Nano-technology can be used to minimize the cost, accelerate the process and
improve the efficiency of industrial waste water treatment. Nanoparticles found
to be one of the best solution in the field of industrial waste water
treatment. 



References

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  • [2] Qu, X., Alvarez, P. J., & Li, Q. (2013). Applications of nanotechnology in water and wastewater treatment. Water research, 47(12), 3931-3946.‏
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  • [18] Tijing, L. D., Woo, Y. C., Choi, J. S., Lee, S., Kim, S. H., & Shon, H. K. (2015). Fouling and its control in membrane distillation—a review. Journal of Membrane Science, 475, 215-244
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  • [20] Choudhury, R. R., Gohil, J. M., Mohanty, S., & Nayak, S. K. (2018). Antifouling, fouling release and antimicrobial materials for surface modification of reverse osmosis and nanofiltration membranes. Journal of Materials Chemistry A, 6(2), 313-333.
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  • [23] Bhat, A. H., Rehman, W. U., Khan, I. U., Khan, I., Ahmad, S., Ayoub, M., & Usmani, M. A. (2018). Nanocomposite membrane for environmental remediation. In Polymer-based Nanocomposites for Energy and Environmental Applications (pp. 407-440).
  • [24] Nakata, K., & Fujishima, A. (2012). TiO2 photocatalysis: Design and applications. Journal of Photochemistry and Photobiology C: Photochemistry Reviews, 13(3), 169-189.‏
  • [25] Güzel, F., Sayğılı, H., Sayğılı, G. A., & Koyuncu, F. (2015). New low-cost nanoporous carbonaceous adsorbent developed from carob (Ceratonia siliqua) processing industry waste for the adsorption of anionic textile dye: characterization, equilibrium and kinetic modeling. Journal of Molecular Liquids, 206, 244-255.‏
  • [26] Liang, R., Hu, A., Hatat-Fraile, M., & Zhou, N. (2014). Fundamentals on Adsorption, Membrane Filtration, and Advanced Oxidation Processes for
  • [27] Roy, K., & Ghosh, C. K. (2017). Environmental and Biological Applications of Nanoparticles. Nanotechnology: Synthesis to Applications. ‏
  • [28] Ramamoorthy, V., Kannan, K., & Thiripuranthagan, S. (2018). Photocatalytic Degradation of Textile Reactive Dyes—A Comparative Study Using Nano Silver Decorated Titania-Silica Composite Photocatalysts. Journal of Nanoscience and Nanotechnology, 18(4), 2921-2930.
  • [29] Roy, K., Sarkar, C. K., & Ghosh, C. K. (2015). Rapid colorimetric detection of Hg2+ ion by green silver nanoparticles synthesized using Dahlia pinnata leaf extract. Green Processing and Synthesis, 4(6), 455-461.
  • [30] Aswin Kumar, I., & Viswanathan, N. (2018). Development and Reuse of Amine-Grafted Chitosan Hybrid Beads in the Retention of Nitrate and Phosphate. Journal of Chemical & Engineering Data.
  • [31] Lofrano, G., Carotenuto, M., Libralato, G., Domingos, R. F., Markus, A., Dini, L., & Chattopadhyaya, M. C. (2016). Polymer functionalized nanocomposites for metals removal from water and wastewater: an overview. Water research, 92, 22-37.
  • [32] Sharma, R., & Kumar, D. (2018). Nanocomposites: An Approach Towards Pollution Control. In Nanocomposites for Pollution Control (pp. 3-46). Pan Stanford.
  • [33] Ray, P. Z., & Shipley, H. J. (2015). Inorganic nano-adsorbents for the removal of heavy metals and arsenic: a review. RSC Advances, 5(38), 29885-29907.‏
  • [34] Percival, R. V., Schroeder, C. H., Miller, A. S., & Leape, J. P. (2017). Environmental regulation: Law, science, and policy. Wolters Kluwer Law & Business.
  • [35] Liu, K., Wang, S., Wu, Q., Wang, L., Ma, Q., Zhang, L., ... & Hao, J. (2018). A Highly-resolved Mercury Emission Inventory of Chinese Coal-fired Power Plants. Environmental science & technology.‏
  • [36] Dhanavel, S., Manivannan, N., Mathivanan, N., Gupta, V. K., Narayanan, V., & Stephen, A. (2018). Preparation and characterization of cross-linked chitosan/palladium nanocomposites for catalytic and antibacterial activity. Journal of Molecular Liquids, 257, 32-41.
Year 2018, Volume: 1 Issue: 3, 71 - 76, 02.07.2018

Abstract

References

  • [1] Kaur, J., Pathak, T., Singh, A., & Kumar, K. (2017). Application of Nanotechnology in the Environment Biotechnology. In Advances in Environmental Biotechnology (pp. 155-165). Springer, Singapore.‏
  • [2] Qu, X., Alvarez, P. J., & Li, Q. (2013). Applications of nanotechnology in water and wastewater treatment. Water research, 47(12), 3931-3946.‏
  • [3] Anis, M., AlTaher, G., Sarhan, W., & Elsemary, M. (2017). Environment and Remediation Applications. In Nanovate (pp. 87-112). Springer, Cham.‏
  • [4] Kagan, C. R., Fernandez, L. E., Gogotsi, Y., Hammond, P. T., Hersam, M. C., Nel, A. E., ... & Weiss, P. S. (2016). Nano Day: celebrating the next decade of nanoscience and nanotechnology.‏
  • [5] Manahan, S. (2017). Environmental chemistry. CRC press.‏
  • [6] Alrumman, S. A., El-kott, A. F., & Keshk, S. M. (2016). Water pollution: source & treatment. American Journal of Environmental Engineering, 6(3), 88-98.‏
  • [7] Mahadik, S. (2017). Applications of Nanotechnology in Water and Waste Water Treatment. AADYA-Journal of Management and Technology (JMT), 7, 187-191.‏
  • [8] Gunti, S., Kumar, A., & Ram, M. K. (2018). Nanostructured photocatalysis in the visible spectrum for the decontamination of air and water. International Materials Reviews, 63(4), 257-282.‏
  • [9] Walsh, S. E., & Denyer, S. P. (2012). Filtration sterilization (pp. 343-370). Wiley‐Blackwell.‏
  • [10] Baruah, S., Khan, M. N., & Dutta, J. (2016). Perspectives and applications of nanotechnology in water treatment. Environmental chemistry letters, 14(1), 1-14.‏
  • [11] Levy, E. (2018). U.S. Patent Application No. 15/839,365.‏
  • [12] Onoyinka, A. A., & Titilayo, H. A. (2017). Accumulation of Lead, Cadmium and Iron in Topsoil of Ori-Ile Battery Waste Dumpsite and Surrounding Gradient Point Areas at Olodo, Ibadan, Nigeria. International Journal of Mineral Processing and Extractive Metallurgy, 2(5), 68.‏
  • [13] Sharma, R., & Kumar, D. (2018). Nanoadsorbents: An Approach Towards Wastewater Treatment. Nanotechnology for Sustainable Water Resources, 371-405.‏
  • [14] Okereke, J. N., Ogidi, O. I., & Obasi, K. O. (2016). Environmental and health impact of industrial wastewater effluents in Nigeria-A Review. Int. J. Adv. Res. Biol. Sci, 3(6), 55-67.‏
  • [15] Voyiatzis, G. A., Kouravelou, K., Karachalios, T., Beobide, A. S., & Anastasopoulos, J. A. (2017). Study of carbon nanotubes’ embedment into porous polymeric membranes for wastewater treatment. In Application of Nanotechnology in Membranes for Water Treatment (pp. 81-110). CRC Press.‏
  • [16] Anastasopoulos, J. A., Beobide, A. S., Karachalios, T., Kouravelou, K., & Voyiatzis, G. A. (2017). Study of carbon nanotubes’ embedment into porous polymeric membranes for wastewater treatment. In Application of Nanotechnology in Membranes for Water Treatment (pp. 141-170). CRC Press.
  • [17] Vilakati, G. D. (2015). Fabrication and characterisation of highly water permeable ultrafiltration membranes as supports for forward osmosis thin film composite membranes (Doctoral dissertation, University of Johannesburg).
  • [18] Tijing, L. D., Woo, Y. C., Choi, J. S., Lee, S., Kim, S. H., & Shon, H. K. (2015). Fouling and its control in membrane distillation—a review. Journal of Membrane Science, 475, 215-244
  • [19] Mohammad, A. W., Teow, Y. H., Ang, W. L., Chung, Y. T., Oatley-Radcliffe, D. L., & Hilal, N. (2015). Nanofiltration membranes review: Recent advances and future prospects. Desalination, 356, 226-254.‏
  • [20] Choudhury, R. R., Gohil, J. M., Mohanty, S., & Nayak, S. K. (2018). Antifouling, fouling release and antimicrobial materials for surface modification of reverse osmosis and nanofiltration membranes. Journal of Materials Chemistry A, 6(2), 313-333.
  • [21] Jeevanandam, J., Barhoum, A., Chan, Y. S., Dufresne, A., & Danquah, M. K. (2018). Review on nanoparticles and nanostructured materials: history, sources, toxicity and regulations. Beilstein journal of nanotechnology, 9, 1050.‏
  • [22] Ying, Y., Liu, D., Zhang, W., Ma, J., Huang, H., Yang, Q., & Zhong, C. (2017). High-Flux Graphene Oxide Membranes Intercalated by Metal–Organic Framework with Highly Selective Separation of Aqueous Organic Solution. ACS applied materials & interfaces, 9(2), 1710-1718.‏
  • [23] Bhat, A. H., Rehman, W. U., Khan, I. U., Khan, I., Ahmad, S., Ayoub, M., & Usmani, M. A. (2018). Nanocomposite membrane for environmental remediation. In Polymer-based Nanocomposites for Energy and Environmental Applications (pp. 407-440).
  • [24] Nakata, K., & Fujishima, A. (2012). TiO2 photocatalysis: Design and applications. Journal of Photochemistry and Photobiology C: Photochemistry Reviews, 13(3), 169-189.‏
  • [25] Güzel, F., Sayğılı, H., Sayğılı, G. A., & Koyuncu, F. (2015). New low-cost nanoporous carbonaceous adsorbent developed from carob (Ceratonia siliqua) processing industry waste for the adsorption of anionic textile dye: characterization, equilibrium and kinetic modeling. Journal of Molecular Liquids, 206, 244-255.‏
  • [26] Liang, R., Hu, A., Hatat-Fraile, M., & Zhou, N. (2014). Fundamentals on Adsorption, Membrane Filtration, and Advanced Oxidation Processes for
  • [27] Roy, K., & Ghosh, C. K. (2017). Environmental and Biological Applications of Nanoparticles. Nanotechnology: Synthesis to Applications. ‏
  • [28] Ramamoorthy, V., Kannan, K., & Thiripuranthagan, S. (2018). Photocatalytic Degradation of Textile Reactive Dyes—A Comparative Study Using Nano Silver Decorated Titania-Silica Composite Photocatalysts. Journal of Nanoscience and Nanotechnology, 18(4), 2921-2930.
  • [29] Roy, K., Sarkar, C. K., & Ghosh, C. K. (2015). Rapid colorimetric detection of Hg2+ ion by green silver nanoparticles synthesized using Dahlia pinnata leaf extract. Green Processing and Synthesis, 4(6), 455-461.
  • [30] Aswin Kumar, I., & Viswanathan, N. (2018). Development and Reuse of Amine-Grafted Chitosan Hybrid Beads in the Retention of Nitrate and Phosphate. Journal of Chemical & Engineering Data.
  • [31] Lofrano, G., Carotenuto, M., Libralato, G., Domingos, R. F., Markus, A., Dini, L., & Chattopadhyaya, M. C. (2016). Polymer functionalized nanocomposites for metals removal from water and wastewater: an overview. Water research, 92, 22-37.
  • [32] Sharma, R., & Kumar, D. (2018). Nanocomposites: An Approach Towards Pollution Control. In Nanocomposites for Pollution Control (pp. 3-46). Pan Stanford.
  • [33] Ray, P. Z., & Shipley, H. J. (2015). Inorganic nano-adsorbents for the removal of heavy metals and arsenic: a review. RSC Advances, 5(38), 29885-29907.‏
  • [34] Percival, R. V., Schroeder, C. H., Miller, A. S., & Leape, J. P. (2017). Environmental regulation: Law, science, and policy. Wolters Kluwer Law & Business.
  • [35] Liu, K., Wang, S., Wu, Q., Wang, L., Ma, Q., Zhang, L., ... & Hao, J. (2018). A Highly-resolved Mercury Emission Inventory of Chinese Coal-fired Power Plants. Environmental science & technology.‏
  • [36] Dhanavel, S., Manivannan, N., Mathivanan, N., Gupta, V. K., Narayanan, V., & Stephen, A. (2018). Preparation and characterization of cross-linked chitosan/palladium nanocomposites for catalytic and antibacterial activity. Journal of Molecular Liquids, 257, 32-41.
There are 36 citations in total.

Details

Primary Language English
Subjects Environmental Sciences
Journal Section Articles
Authors

Ahmed Hasham This is me 0000-0002-0202-6664

Publication Date July 2, 2018
Submission Date September 5, 2018
Published in Issue Year 2018 Volume: 1 Issue: 3

Cite

APA Hasham, A. (2018). Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review. International Journal of Environmental Pollution and Environmental Modelling, 1(3), 71-76.
AMA Hasham A. Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review. Int. j. environ. pollut. environ. model. July 2018;1(3):71-76.
Chicago Hasham, Ahmed. “Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review”. International Journal of Environmental Pollution and Environmental Modelling 1, no. 3 (July 2018): 71-76.
EndNote Hasham A (July 1, 2018) Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review. International Journal of Environmental Pollution and Environmental Modelling 1 3 71–76.
IEEE A. Hasham, “Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review”, Int. j. environ. pollut. environ. model., vol. 1, no. 3, pp. 71–76, 2018.
ISNAD Hasham, Ahmed. “Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review”. International Journal of Environmental Pollution and Environmental Modelling 1/3 (July 2018), 71-76.
JAMA Hasham A. Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review. Int. j. environ. pollut. environ. model. 2018;1:71–76.
MLA Hasham, Ahmed. “Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review”. International Journal of Environmental Pollution and Environmental Modelling, vol. 1, no. 3, 2018, pp. 71-76.
Vancouver Hasham A. Selected Nanotechnology Applications in Industrial Waste Water Treatment: A Review. Int. j. environ. pollut. environ. model. 2018;1(3):71-6.
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